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windows-xp/Source/XPSP1/NT/ds/security/passport/atlmfc/atlcoll.h

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// This is a part of the Active Template Library.
// Copyright (C) 1996-2001 Microsoft Corporation
// All rights reserved.
//
// This source code is only intended as a supplement to the
// Active Template Library Reference and related
// electronic documentation provided with the library.
// See these sources for detailed information regarding the
// Active Template Library product.
#ifndef __ATLCOLL_H__
#define __ATLCOLL_H__
#pragma once
#pragma warning(push)
#pragma warning(disable: 4702) // Unreachable code. This file will have lots of it, especially without EH enabled.
#pragma warning(disable: 4512) // assignment operator could not be generated
#pragma warning(disable: 4290) // C++ Exception Specification ignored
// abstract iteration position
#ifndef _AFX
struct __POSITION
{
};
#endif
typedef __POSITION* POSITION;
#include <atlbase.h>
//REVIEW: Just to fix VSEE
#pragma push_macro("min")
#pragma push_macro("max")
#undef min
#undef max
#define min(a,b) (((a) < (b)) ? (a) : (b))
#define max(a,b) (((a) > (b)) ? (a) : (b))
#include <new.h>
#ifndef _AFX_PACKING
#define _AFX_PACKING 4
#endif
namespace ATL {
struct CAtlPlex // warning variable length structure
{
CAtlPlex* pNext;
#if (_AFX_PACKING >= 8)
DWORD dwReserved[1]; // align on 8 byte boundary
#endif
// BYTE data[maxNum*elementSize];
void* data() { return this+1; }
static CAtlPlex* Create(CAtlPlex*& head, size_t nMax, size_t cbElement);
// like 'calloc' but no zero fill
// may throw memory exceptions
void FreeDataChain(); // free this one and links
};
inline CAtlPlex* CAtlPlex::Create( CAtlPlex*& pHead, size_t nMax, size_t nElementSize )
{
CAtlPlex* pPlex;
ATLASSERT( nMax > 0 );
ATLASSERT( nElementSize > 0 );
pPlex = static_cast< CAtlPlex* >( malloc( sizeof( CAtlPlex )+(nMax*nElementSize) ) );
if( pPlex == NULL )
{
return( NULL );
}
pPlex->pNext = pHead;
pHead = pPlex;
return( pPlex );
}
inline void CAtlPlex::FreeDataChain()
{
CAtlPlex* pPlex;
pPlex = this;
while( pPlex != NULL )
{
CAtlPlex* pNext;
pNext = pPlex->pNext;
free( pPlex );
pPlex = pNext;
}
}
template< typename T >
class CElementTraitsBase
{
public:
typedef const T& INARGTYPE;
typedef T& OUTARGTYPE;
static void CopyElements( T* pDest, const T* pSrc, size_t nElements )
{
for( size_t iElement = 0; iElement < nElements; iElement++ )
{
pDest[iElement] = pSrc[iElement];
}
}
static void RelocateElements( T* pDest, T* pSrc, size_t nElements )
{
// A simple memmove works for nearly all types.
// You'll have to override this for types that have pointers to their
// own members.
memmove( pDest, pSrc, nElements*sizeof( T ) );
}
};
template< typename T >
class CDefaultHashTraits
{
public:
static ULONG Hash( const T& element ) throw()
{
return( ULONG( ULONG_PTR( element ) ) );
}
};
template< typename T >
class CDefaultCompareTraits
{
public:
static bool CompareElements( const T& element1, const T& element2 )
{
return( (element1 == element2) != 0 ); // != 0 to handle overloads of operator== that return BOOL instead of bool
}
static int CompareElementsOrdered( const T& element1, const T& element2 )
{
if( element1 < element2 )
{
return( -1 );
}
else if( element1 == element2 )
{
return( 0 );
}
else
{
ATLASSERT( element1 > element2 );
return( 1 );
}
}
};
template< typename T >
class CDefaultElementTraits :
public CElementTraitsBase< T >,
public CDefaultHashTraits< T >,
public CDefaultCompareTraits< T >
{
};
template< typename T >
class CElementTraits :
public CDefaultElementTraits< T >
{
};
template<>
class CElementTraits< GUID > :
public CElementTraitsBase< T >
{
public:
static ULONG Hash( INARGTYPE guid )
{
const DWORD* pdwData = reinterpret_cast< const DWORD* >( &guid );
return( pdwData[0]^pdwData[1]^pdwData[2]^pdwData[3] );
}
static bool CompareElements( INARGTYPE element1, INARGTYPE element2 )
{
return( (element1 == element2) != 0 ); // != 0 to handle overloads of operator== that return BOOL instead of bool
}
static int CompareElementsOrdered( INARGTYPE element1, INARGTYPE element2 )
{
const DWORD* pdwData1 = reinterpret_cast< const DWORD* >( &element1 );
const DWORD* pdwData2 = reinterpret_cast< const DWORD* >( &element2 );
for( int iDWORD = 3; iDWORD >= 0; iDWORD-- )
{
if( pdwData1[iDWORD] > pdwData2[iDWORD] )
{
return( 1 );
}
else if( pdwData1[iDWORD] < pdwData2[iDWORD] )
{
return( -1 );
}
}
return( 0 );
}
};
template<>
class CElementTraits< CComVariant > :
public CElementTraitsBase< CComVariant >
{
public:
typedef const VARIANT& INARGTYPE;
// static ULONG Hash( INARGTYPE t ); // variant hashing is problematic
static bool CompareElements( INARGTYPE element1, INARGTYPE element2 )
{
return VarCmp(const_cast<VARIANT*>(&element1), const_cast<VARIANT*>(&element2), LOCALE_USER_DEFAULT, 0)==VARCMP_EQ;
}
static int CompareElementsOrdered( INARGTYPE element1, INARGTYPE element2 )
{
HRESULT hr = VarCmp(const_cast<VARIANT*>(&element1), const_cast<VARIANT*>(&element2), LOCALE_USER_DEFAULT, 0);
if( hr == VARCMP_LT )
{
return( -1 );
}
else if( hr == VARCMP_GT )
{
return( 1 );
}
else
{
ATLASSERT( hr == VARCMP_EQ || hr == VARCMP_NULL );
return( 0 );
}
}
};
template<>
class CElementTraits< CComBSTR > :
public CElementTraitsBase< CComBSTR >
{
public:
static ULONG Hash( INARGTYPE bstr ) throw()
{
ULONG nHash = 0;
const OLECHAR* pch = bstr;
ULONG nLength = bstr.Length();
for( ULONG iChar = 0; iChar < nLength; iChar++ )
{
nHash = (nHash<<5)+nHash+pch[iChar];
}
return( nHash );
}
static bool CompareElements( INARGTYPE bstr1, INARGTYPE bstr2 ) throw()
{
return( bstr1 == bstr2 );
}
static int CompareElementsOrdered( INARGTYPE bstr1, INARGTYPE bstr2 ) throw()
{
if( bstr1 == NULL )
{
return( (bstr2 == NULL) ? 0 : -1 );
}
else if( bstr2 == NULL )
{
return( 1 );
}
HRESULT hr = VarBstrCmp( bstr1, bstr2, LOCALE_SYSTEM_DEFAULT, 0 );
switch( hr )
{
case VARCMP_LT:
return( -1 );
break;
case VARCMP_GT:
return( 1 );
break;
case VARCMP_EQ:
return( 0 );
break;
default:
ATLASSERT( false );
return( 0 );
break;
}
}
};
template< typename I, const IID* piid = &__uuidof( I ) >
class CComQIPtrElementTraits :
public CDefaultElementTraits< ATL::CComQIPtr< I, piid > >
{
public:
typedef I* INARGTYPE;
};
template< typename T >
class CAutoPtrElementTraits :
public CDefaultElementTraits< ATL::CAutoPtr< T > >
{
public:
typedef ATL::CAutoPtr< T >& INARGTYPE;
typedef T*& OUTARGTYPE;
};
template< typename T >
class CAutoVectorPtrElementTraits :
public CDefaultElementTraits< ATL::CAutoVectorPtr< T > >
{
public:
typedef ATL::CAutoVectorPtr< T >& INARGTYPE;
typedef T*& OUTARGTYPE;
};
template< typename T, class Allocator = ATL::CCRTAllocator >
class CHeapPtrElementTraits :
public CDefaultElementTraits< ATL::CHeapPtr< T, Allocator > >
{
public:
typedef ATL::CHeapPtr< T, Allocator >& INARGTYPE;
typedef T*& OUTARGTYPE;
};
template< typename T >
class CStringElementTraits :
public CElementTraitsBase< T >
{
public:
typedef T::PCXSTR INARGTYPE;
typedef T& OUTARGTYPE;
static ULONG Hash( INARGTYPE str )
{
ATLASSERT( str != NULL );
ULONG nHash = 0;
const T::XCHAR* pch = str;
while( *pch != 0 )
{
nHash = (nHash<<5)+nHash+(*pch);
pch++;
}
return( nHash );
}
static bool CompareElements( INARGTYPE str1, INARGTYPE str2 )
{
return( T::StrTraits::StringCompare( str1, str2 ) == 0 );
}
static int CompareElementsOrdered( INARGTYPE str1, INARGTYPE str2 )
{
return( T::StrTraits::StringCompare( str1, str2 ) );
}
};
template < typename T >
class CDefaultCharTraits
{
};
template <>
class CDefaultCharTraits<char>
{
public:
static char CharToUpper(char x)
{
return (char)toupper(x);
}
static char CharToLower(char x)
{
return (char)tolower(x);
}
};
template <>
class CDefaultCharTraits<wchar_t>
{
public:
static wchar_t CharToUpper(wchar_t x)
{
return (wchar_t)towupper(x);
}
static wchar_t CharToLower(wchar_t x)
{
return (wchar_t)towlower(x);
}
};
template< typename T, class CharTraits = CDefaultCharTraits<T::XCHAR> >
class CStringElementTraitsI :
public CElementTraitsBase< T >
{
public:
typedef T::PCXSTR INARGTYPE;
typedef T& OUTARGTYPE;
static ULONG Hash( INARGTYPE str )
{
const T::XCHAR* pch;
ULONG nHash;
ATLASSERT( str != NULL );
nHash = 0;
pch = str;
while( *pch != 0 )
{
nHash = (nHash<<5)+nHash+CharTraits::CharToUpper(*pch);
pch++;
}
return( nHash );
}
static bool CompareElements( INARGTYPE str1, INARGTYPE str2 )
{
return( T::StrTraits::StringCompareIgnore( str1, str2 ) == 0 );
}
static int CompareElementsOrdered( INARGTYPE str1, INARGTYPE str2 )
{
return( T::StrTraits::StringCompareIgnore( str1, str2 ) );
}
};
template< typename T >
class CStringRefElementTraits :
public CElementTraitsBase< T >
{
public:
static ULONG Hash( INARGTYPE str ) throw()
{
ULONG nHash = 0;
const T::XCHAR* pch = str;
while( *pch != 0 )
{
nHash = (nHash<<5)+nHash+(*pch);
pch++;
}
return( nHash );
}
static bool CompareElements( INARGTYPE element1, INARGTYPE element2 ) throw()
{
return( element1 == element2 );
}
static int CompareElementsOrdered( INARGTYPE str1, INARGTYPE str2 ) throw()
{
return( str1.Compare( str2 ) );
}
};
template< typename T >
class CPrimitiveElementTraits :
public CDefaultElementTraits< T >
{
public:
typedef T INARGTYPE;
typedef T& OUTARGTYPE;
};
#define _DECLARE_PRIMITIVE_TRAITS( T ) \
template<> \
class CElementTraits< T > : \
public CPrimitiveElementTraits< T > \
{ \
};
_DECLARE_PRIMITIVE_TRAITS( unsigned char )
_DECLARE_PRIMITIVE_TRAITS( unsigned short )
_DECLARE_PRIMITIVE_TRAITS( unsigned int )
_DECLARE_PRIMITIVE_TRAITS( unsigned long )
_DECLARE_PRIMITIVE_TRAITS( unsigned __int64 )
_DECLARE_PRIMITIVE_TRAITS( signed char )
_DECLARE_PRIMITIVE_TRAITS( char )
_DECLARE_PRIMITIVE_TRAITS( short )
_DECLARE_PRIMITIVE_TRAITS( int )
_DECLARE_PRIMITIVE_TRAITS( long )
_DECLARE_PRIMITIVE_TRAITS( __int64 )
_DECLARE_PRIMITIVE_TRAITS( float )
_DECLARE_PRIMITIVE_TRAITS( double )
_DECLARE_PRIMITIVE_TRAITS( bool )
#ifdef _NATIVE_WCHAR_T_DEFINED
_DECLARE_PRIMITIVE_TRAITS( wchar_t )
#endif
_DECLARE_PRIMITIVE_TRAITS( void* )
template< typename E, class ETraits = CElementTraits< E > >
class CAtlArray
{
public:
typedef ETraits::INARGTYPE INARGTYPE;
typedef ETraits::OUTARGTYPE OUTARGTYPE;
public:
CAtlArray() throw();
size_t GetCount() const throw();
bool IsEmpty() const throw();
bool SetCount( size_t nNewSize, int nGrowBy = -1 );
void FreeExtra() throw();
void RemoveAll() throw();
const E& GetAt( size_t iElement ) const throw();
void SetAt( size_t iElement, INARGTYPE element );
E& GetAt( size_t iElement ) throw();
const E* GetData() const throw();
E* GetData() throw();
void SetAtGrow( size_t iElement, INARGTYPE element );
// Add an empty element to the end of the array
size_t Add();
// Add an element to the end of the array
size_t Add( INARGTYPE element );
size_t Append( const CAtlArray< E, ETraits >& aSrc );
void Copy( const CAtlArray< E, ETraits >& aSrc );
const E& operator[]( size_t iElement ) const throw();
E& operator[]( size_t iElement ) throw();
void InsertAt( size_t iElement, INARGTYPE element, size_t nCount = 1 );
void InsertArrayAt( size_t iStart, const CAtlArray< E, ETraits >* paNew );
void RemoveAt( size_t iElement, size_t nCount = 1 );
#ifdef _DEBUG
void AssertValid() const;
#endif // _DEBUG
private:
bool GrowBuffer( size_t nNewSize );
// Implementation
private:
E* m_pData;
size_t m_nSize;
size_t m_nMaxSize;
int m_nGrowBy;
private:
static void CallConstructors( E* pElements, size_t nElements );
static void CallDestructors( E* pElements, size_t nElements );
public:
~CAtlArray() throw();
private:
// Private to prevent use
CAtlArray( const CAtlArray& ) throw();
CAtlArray& operator=( const CAtlArray& ) throw();
};
template< class I, const IID* piid = &__uuidof( I ) >
class CInterfaceArray :
public CAtlArray< ATL::CComQIPtr< I, piid >, CComQIPtrElementTraits< I, piid > >
{
public:
CInterfaceArray() throw()
{
}
private:
// Private to prevent use
CInterfaceArray( const CInterfaceArray& ) throw();
CInterfaceArray& operator=( const CInterfaceArray& ) throw();
};
template< typename E >
class CAutoPtrArray :
public CAtlArray< ATL::CAutoPtr< E >, CAutoPtrElementTraits< E > >
{
public:
CAutoPtrArray() throw()
{
}
private:
// Private to prevent use
CAutoPtrArray( const CAutoPtrArray& ) throw();
CAutoPtrArray& operator=( const CAutoPtrArray& ) throw();
};
template< typename E, class Allocator = ATL::CCRTAllocator >
class CHeapPtrArray :
public CAtlArray< ATL::CHeapPtr< E, Allocator >, CHeapPtrElementTraits< E, Allocator > >
{
public:
CHeapPtrArray() throw()
{
}
private:
// Private to prevent use
CHeapPtrArray( const CHeapPtrArray& ) throw();
CHeapPtrArray& operator=( const CHeapPtrArray& ) throw();
};
template< typename E, class ETraits >
inline size_t CAtlArray< E, ETraits >::GetCount() const
{
return( m_nSize );
}
template< typename E, class ETraits >
inline bool CAtlArray< E, ETraits >::IsEmpty() const
{
return( m_nSize == 0 );
}
template< typename E, class ETraits >
inline void CAtlArray< E, ETraits >::RemoveAll()
{
SetCount( 0, -1 );
}
template< typename E, class ETraits >
inline const E& CAtlArray< E, ETraits >::GetAt( size_t iElement ) const
{
ATLASSERT( iElement < m_nSize );
return( m_pData[iElement] );
}
template< typename E, class ETraits >
inline void CAtlArray< E, ETraits >::SetAt( size_t iElement, INARGTYPE element )
{
ATLASSERT( iElement < m_nSize );
m_pData[iElement] = element;
}
template< typename E, class ETraits >
inline E& CAtlArray< E, ETraits >::GetAt( size_t iElement )
{
ATLASSERT( iElement < m_nSize );
return( m_pData[iElement] );
}
template< typename E, class ETraits >
inline const E* CAtlArray< E, ETraits >::GetData() const
{
return( m_pData );
}
template< typename E, class ETraits >
inline E* CAtlArray< E, ETraits >::GetData()
{
return( m_pData );
}
template< typename E, class ETraits >
inline size_t CAtlArray< E, ETraits >::Add()
{
size_t iElement;
iElement = m_nSize;
SetCount( m_nSize+1 );
return( iElement );
}
#pragma push_macro("new")
#undef new
template< typename E, class ETraits >
inline size_t CAtlArray< E, ETraits >::Add( INARGTYPE element )
{
size_t iElement;
iElement = m_nSize;
if( iElement >= m_nMaxSize )
{
bool bSuccess = GrowBuffer( iElement+1 );
if( !bSuccess )
{
ATL::AtlThrow( E_OUTOFMEMORY );
}
}
::new( m_pData+iElement ) E( element );
m_nSize++;
return( iElement );
}
#pragma pop_macro("new")
template< typename E, class ETraits >
inline const E& CAtlArray< E, ETraits >::operator[]( size_t iElement ) const
{
ATLASSERT( iElement < m_nSize );
return( m_pData[iElement] );
}
template< typename E, class ETraits >
inline E& CAtlArray< E, ETraits >::operator[]( size_t iElement )
{
ATLASSERT( iElement < m_nSize );
return( m_pData[iElement] );
}
template< typename E, class ETraits >
CAtlArray< E, ETraits >::CAtlArray() :
m_pData( NULL ),
m_nSize( 0 ),
m_nMaxSize( 0 ),
m_nGrowBy( 0 )
{
}
template< typename E, class ETraits >
CAtlArray< E, ETraits >::~CAtlArray()
{
if( m_pData != NULL )
{
CallDestructors( m_pData, m_nSize );
free( m_pData );
}
}
template< typename E, class ETraits >
bool CAtlArray< E, ETraits >::GrowBuffer( size_t nNewSize )
{
if( nNewSize > m_nMaxSize )
{
if( m_pData == NULL )
{
size_t nAllocSize = max( size_t( m_nGrowBy ), nNewSize );
m_pData = static_cast< E* >( malloc( nAllocSize*sizeof( E ) ) );
if( m_pData == NULL )
{
return( false );
}
m_nMaxSize = nAllocSize;
}
else
{
// otherwise, grow array
size_t nGrowBy = m_nGrowBy;
if( nGrowBy == 0 )
{
// heuristically determine growth when nGrowBy == 0
// (this avoids heap fragmentation in many situations)
nGrowBy = m_nSize/8;
nGrowBy = (nGrowBy < 4) ? 4 : ((nGrowBy > 1024) ? 1024 : nGrowBy);
}
size_t nNewMax;
if( nNewSize < (m_nMaxSize+nGrowBy) )
nNewMax = m_nMaxSize+nGrowBy; // granularity
else
nNewMax = nNewSize; // no slush
ATLASSERT( nNewMax >= m_nMaxSize ); // no wrap around
#ifdef SIZE_T_MAX
ATLASSERT( nNewMax <= SIZE_T_MAX/sizeof( E ) ); // no overflow
#endif
E* pNewData = static_cast< E* >( malloc( nNewMax*sizeof( E ) ) );
if( pNewData == NULL )
{
return false;
}
// copy new data from old
ETraits::RelocateElements( pNewData, m_pData, m_nSize );
// get rid of old stuff (note: no destructors called)
free( m_pData );
m_pData = pNewData;
m_nMaxSize = nNewMax;
}
}
return true;
}
template< typename E, class ETraits >
bool CAtlArray< E, ETraits >::SetCount( size_t nNewSize, int nGrowBy )
{
ATLASSERT_VALID(this);
if( nGrowBy != -1 )
{
m_nGrowBy = nGrowBy; // set new size
}
if( nNewSize == 0 )
{
// shrink to nothing
if( m_pData != NULL )
{
CallDestructors( m_pData, m_nSize );
free( m_pData );
m_pData = NULL;
}
m_nSize = 0;
m_nMaxSize = 0;
}
else if( nNewSize <= m_nMaxSize )
{
// it fits
if( nNewSize > m_nSize )
{
// initialize the new elements
CallConstructors( m_pData+m_nSize, nNewSize-m_nSize );
}
else if( m_nSize > nNewSize )
{
// destroy the old elements
CallDestructors( m_pData+nNewSize, m_nSize-nNewSize );
}
m_nSize = nNewSize;
}
else
{
bool bSuccess;
bSuccess = GrowBuffer( nNewSize );
if( !bSuccess )
{
return( false );
}
// construct new elements
ATLASSERT( nNewSize > m_nSize );
CallConstructors( m_pData+m_nSize, nNewSize-m_nSize );
m_nSize = nNewSize;
}
return true;
}
template< typename E, class ETraits >
size_t CAtlArray< E, ETraits >::Append( const CAtlArray< E, ETraits >& aSrc )
{
ATLASSERT_VALID(this);
ATLASSERT( this != &aSrc ); // cannot append to itself
size_t nOldSize = m_nSize;
SetCount( m_nSize+aSrc.m_nSize );
ETraits::CopyElements( m_pData+nOldSize, aSrc.m_pData, aSrc.m_nSize );
return( nOldSize );
}
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::Copy( const CAtlArray< E, ETraits >& aSrc )
{
ATLASSERT_VALID(this);
ATLASSERT( this != &aSrc ); // cannot append to itself
SetCount( aSrc.m_nSize );
ETraits::CopyElements( m_pData, aSrc.m_pData, aSrc.m_nSize );
}
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::FreeExtra()
{
ATLASSERT_VALID(this);
if( m_nSize != m_nMaxSize )
{
// shrink to desired size
#ifdef SIZE_T_MAX
ATLASSERT( m_nSize <= (SIZE_T_MAX/sizeof( E )) ); // no overflow
#endif
E* pNewData = NULL;
if( m_nSize != 0 )
{
pNewData = (E*)malloc( m_nSize*sizeof( E ) );
if( pNewData == NULL )
{
return;
}
// copy new data from old
ETraits::RelocateElements( pNewData, m_pData, m_nSize );
}
// get rid of old stuff (note: no destructors called)
free( m_pData );
m_pData = pNewData;
m_nMaxSize = m_nSize;
}
}
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::SetAtGrow( size_t iElement, INARGTYPE element )
{
ATLASSERT_VALID(this);
size_t nOldSize;
nOldSize = m_nSize;
if( iElement >= m_nSize )
SetCount( iElement+1, -1 );
_ATLTRY
{
m_pData[iElement] = element;
}
_ATLCATCHALL()
{
if( m_nSize != nOldSize )
{
SetCount( nOldSize, -1 );
}
_ATLRETHROW;
}
}
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::InsertAt( size_t iElement, INARGTYPE element, size_t nElements /*=1*/)
{
ATLASSERT_VALID(this);
ATLASSERT( nElements > 0 ); // zero size not allowed
if( iElement >= m_nSize )
{
// adding after the end of the array
SetCount( iElement+nElements, -1 ); // grow so nIndex is valid
}
else
{
// inserting in the middle of the array
size_t nOldSize = m_nSize;
SetCount( m_nSize+nElements, -1 ); // grow it to new size
// destroy intial data before copying over it
CallDestructors( m_pData+nOldSize, nElements );
// shift old data up to fill gap
ETraits::RelocateElements( m_pData+(iElement+nElements), m_pData+iElement,
nOldSize-iElement );
_ATLTRY
{
// re-init slots we copied from
CallConstructors( m_pData+iElement, nElements );
}
_ATLCATCHALL()
{
ETraits::RelocateElements( m_pData+iElement, m_pData+(iElement+nElements),
nOldSize-iElement );
SetCount( nOldSize, -1 );
_ATLRETHROW;
}
}
// insert new value in the gap
ATLASSERT( (iElement+nElements) <= m_nSize );
for( size_t iNewElement = iElement; iNewElement < (iElement+nElements); iNewElement++ )
{
m_pData[iNewElement] = element;
}
}
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::RemoveAt( size_t iElement, size_t nElements )
{
ATLASSERT_VALID(this);
ATLASSERT( (iElement+nElements) <= m_nSize );
// just remove a range
size_t nMoveCount = m_nSize-(iElement+nElements);
CallDestructors( m_pData+iElement, nElements );
if( nMoveCount > 0 )
{
ETraits::RelocateElements( m_pData+iElement, m_pData+(iElement+nElements),
nMoveCount );
}
m_nSize -= nElements;
}
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::InsertArrayAt( size_t iStartElement,
const CAtlArray< E, ETraits >* paNew )
{
ATLASSERT_VALID(this);
ATLASSERT( paNew != NULL );
ATLASSERT_VALID(paNew);
if( paNew->GetCount() > 0 )
{
InsertAt( iStartElement, paNew->GetAt( 0 ), paNew->GetCount() );
for( size_t iElement = 0; iElement < paNew->GetCount(); iElement++ )
SetAt( iStartElement+iElement, paNew->GetAt( iElement ) );
}
}
#ifdef _DEBUG
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::AssertValid() const
{
if( m_pData == NULL )
{
ATLASSERT( m_nSize == 0 );
ATLASSERT( m_nMaxSize == 0 );
}
else
{
ATLASSERT( m_nSize <= m_nMaxSize );
ATLASSERT( AtlIsValidAddress( m_pData, m_nMaxSize * sizeof( E ) ) );
}
}
#endif
#pragma push_macro("new")
#undef new
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::CallConstructors( E* pElements, size_t nElements )
{
size_t iElement;
_ATLTRY
{
for( iElement = 0; iElement < nElements; iElement++ )
{
::new( pElements+iElement ) E;
}
}
_ATLCATCHALL()
{
while( iElement > 0 )
{
iElement--;
pElements[iElement].~E();
}
_ATLRETHROW;
}
}
#pragma pop_macro("new")
template< typename E, class ETraits >
void CAtlArray< E, ETraits >::CallDestructors( E* pElements, size_t nElements )
{
(void)pElements; //REVIEW: Unreferenced formal warning if T doesn't have a real destructor
for( size_t iElement = 0; iElement < nElements; iElement++ )
{
pElements[iElement].~E();
}
}
template< typename E, class ETraits = CElementTraits< E > >
class CAtlList
{
public:
typedef ETraits::INARGTYPE INARGTYPE;
private:
class CNode :
public __POSITION
{
public:
CNode()
{
}
CNode( INARGTYPE element ) :
m_element( element )
{
}
~CNode() throw()
{
}
public:
CNode* m_pNext;
CNode* m_pPrev;
E m_element;
private:
CNode( const CNode& ) throw();
};
public:
CAtlList( UINT nBlockSize = 10 ) throw();
size_t GetCount() const throw();
bool IsEmpty() const throw();
E& GetHead() throw();
const E& GetHead() const throw();
E& GetTail() throw();
const E& GetTail() const throw();
E RemoveHead();
E RemoveTail();
void RemoveHeadNoReturn() throw();
void RemoveTailNoReturn() throw();
POSITION AddHead();
POSITION AddHead( INARGTYPE element );
void AddHeadList( const CAtlList< E, ETraits >* plNew );
POSITION AddTail();
POSITION AddTail( INARGTYPE element );
void AddTailList( const CAtlList< E, ETraits >* plNew );
void RemoveAll() throw();
POSITION GetHeadPosition() const throw();
POSITION GetTailPosition() const throw();
E& GetNext( POSITION& pos ) throw();
const E& GetNext( POSITION& pos ) const throw();
E& GetPrev( POSITION& pos ) throw();
const E& GetPrev( POSITION& pos ) const throw();
E& GetAt( POSITION pos ) throw();
const E& GetAt( POSITION pos ) const throw();
void SetAt( POSITION pos, INARGTYPE element );
void RemoveAt( POSITION pos ) throw();
POSITION InsertBefore( POSITION pos, INARGTYPE element );
POSITION InsertAfter( POSITION pos, INARGTYPE element );
POSITION Find( INARGTYPE element, POSITION posStartAfter = NULL ) const throw();
POSITION FindIndex( size_t iElement ) const throw();
void MoveToHead( POSITION pos ) throw();
void MoveToTail( POSITION pos ) throw();
void SwapElements( POSITION pos1, POSITION pos2 ) throw();
#ifdef _DEBUG
void AssertValid() const;
#endif // _DEBUG
// Implementation
private:
CNode* m_pHead;
CNode* m_pTail;
size_t m_nElements;
CAtlPlex* m_pBlocks;
CNode* m_pFree;
UINT m_nBlockSize;
private:
void GetFreeNode();
CNode* NewNode( CNode* pPrev, CNode* pNext );
CNode* NewNode( INARGTYPE element, CNode* pPrev, CNode* pNext );
void FreeNode( CNode* pNode ) throw();
public:
~CAtlList() throw();
private:
// Private to prevent use
CAtlList( const CAtlList& ) throw();
CAtlList& operator=( const CAtlList& ) throw();
};
template< class I, const IID* piid = &__uuidof( I ) >
class CInterfaceList :
public CAtlList< ATL::CComQIPtr< I, piid >, CComQIPtrElementTraits< I, piid > >
{
public:
CInterfaceList( UINT nBlockSize = 10 ) throw() :
CAtlList< ATL::CComQIPtr< I, piid >, CComQIPtrElementTraits< I, piid > >( nBlockSize )
{
}
private:
// Private to prevent use
CInterfaceList( const CInterfaceList& ) throw();
CInterfaceList& operator=( const CInterfaceList& ) throw();
};
template< typename E >
class CAutoPtrList :
public CAtlList< ATL::CAutoPtr< E >, CAutoPtrElementTraits< E > >
{
public:
CAutoPtrList( UINT nBlockSize = 10 ) throw() :
CAtlList< ATL::CAutoPtr< E >, CAutoPtrElementTraits< E > >( nBlockSize )
{
}
private:
// Private to prevent use
CAutoPtrList( const CAutoPtrList& ) throw();
CAutoPtrList& operator=( const CAutoPtrList& ) throw();
};
template< typename E, class Allocator = ATL::CCRTAllocator >
class CHeapPtrList :
public CAtlList< ATL::CHeapPtr< E, Allocator >, CHeapPtrElementTraits< E, Allocator > >
{
public:
CHeapPtrList( UINT nBlockSize = 10 ) throw() :
CAtlList< ATL::CHeapPtr< E, Allocator >, CHeapPtrElementTraits< E, Allocator > >( nBlockSize )
{
}
private:
// Private to prevent use
CHeapPtrList( const CHeapPtrList& ) throw();
CHeapPtrList& operator=( const CHeapPtrList& ) throw();
};
template< typename E, class ETraits >
inline size_t CAtlList< E, ETraits >::GetCount() const
{
return( m_nElements );
}
template< typename E, class ETraits >
inline bool CAtlList< E, ETraits >::IsEmpty() const
{
return( m_nElements == 0 );
}
template< typename E, class ETraits >
inline E& CAtlList< E, ETraits >::GetHead()
{
ATLASSERT( m_pHead != NULL );
return( m_pHead->m_element );
}
template< typename E, class ETraits >
inline const E& CAtlList< E, ETraits >::GetHead() const
{
ATLASSERT( m_pHead != NULL );
return( m_pHead->m_element );
}
template< typename E, class ETraits >
inline E& CAtlList< E, ETraits >::GetTail()
{
ATLASSERT( m_pTail != NULL );
return( m_pTail->m_element );
}
template< typename E, class ETraits >
inline const E& CAtlList< E, ETraits >::GetTail() const
{
ATLASSERT( m_pTail != NULL );
return( m_pTail->m_element );
}
template< typename E, class ETraits >
inline POSITION CAtlList< E, ETraits >::GetHeadPosition() const
{
return( POSITION( m_pHead ) );
}
template< typename E, class ETraits >
inline POSITION CAtlList< E, ETraits >::GetTailPosition() const
{
return( POSITION( m_pTail ) );
}
template< typename E, class ETraits >
inline E& CAtlList< E, ETraits >::GetNext( POSITION& pos )
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pos = POSITION( pNode->m_pNext );
return( pNode->m_element );
}
template< typename E, class ETraits >
inline const E& CAtlList< E, ETraits >::GetNext( POSITION& pos ) const
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pos = POSITION( pNode->m_pNext );
return( pNode->m_element );
}
template< typename E, class ETraits >
inline E& CAtlList< E, ETraits >::GetPrev( POSITION& pos )
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pos = POSITION( pNode->m_pPrev );
return( pNode->m_element );
}
template< typename E, class ETraits >
inline const E& CAtlList< E, ETraits >::GetPrev( POSITION& pos ) const
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pos = POSITION( pNode->m_pPrev );
return( pNode->m_element );
}
template< typename E, class ETraits >
inline E& CAtlList< E, ETraits >::GetAt( POSITION pos )
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
return( pNode->m_element );
}
template< typename E, class ETraits >
inline const E& CAtlList< E, ETraits >::GetAt( POSITION pos ) const
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
return( pNode->m_element );
}
template< typename E, class ETraits >
inline void CAtlList< E, ETraits >::SetAt( POSITION pos, INARGTYPE element )
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pNode->m_element = element;
}
template< typename E, class ETraits >
CAtlList< E, ETraits >::CAtlList( UINT nBlockSize ) :
m_nElements( 0 ),
m_pHead( NULL ),
m_pTail( NULL ),
m_nBlockSize( nBlockSize ),
m_pBlocks( NULL ),
m_pFree( NULL )
{
ATLASSERT( nBlockSize > 0 );
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::RemoveAll()
{
while( m_nElements > 0 )
{
CNode* pKill;
pKill = m_pHead;
ATLASSERT( pKill != NULL );
m_pHead = m_pHead->m_pNext;
FreeNode( pKill );
}
ATLASSERT( m_nElements == 0 );
m_pHead = NULL;
m_pTail = NULL;
m_pFree = NULL;
m_pBlocks->FreeDataChain();
m_pBlocks = NULL;
}
template< typename E, class ETraits >
CAtlList< E, ETraits >::~CAtlList()
{
RemoveAll();
ATLASSERT( m_nElements == 0 );
}
#pragma push_macro("new")
#undef new
template< typename E, class ETraits >
void CAtlList< E, ETraits >::GetFreeNode()
{
if( m_pFree == NULL )
{
CAtlPlex* pPlex;
CNode* pNode;
pPlex = CAtlPlex::Create( m_pBlocks, m_nBlockSize, sizeof( CNode ) );
if( pPlex == NULL )
{
ATL::AtlThrow( E_OUTOFMEMORY );
}
pNode = (CNode*)pPlex->data();
pNode += m_nBlockSize-1;
for( int iBlock = m_nBlockSize-1; iBlock >= 0; iBlock-- )
{
pNode->m_pNext = m_pFree;
m_pFree = pNode;
pNode--;
}
}
ATLASSERT( m_pFree != NULL );
}
template< typename E, class ETraits >
CAtlList< E, ETraits >::CNode* CAtlList< E, ETraits >::NewNode( CNode* pPrev, CNode* pNext )
{
GetFreeNode();
CNode* pNewNode = m_pFree;
CNode* pNextFree = m_pFree->m_pNext;
::new( pNewNode ) CNode;
m_pFree = pNextFree;
pNewNode->m_pPrev = pPrev;
pNewNode->m_pNext = pNext;
m_nElements++;
ATLASSERT( m_nElements > 0 );
return( pNewNode );
}
template< typename E, class ETraits >
CAtlList< E, ETraits >::CNode* CAtlList< E, ETraits >::NewNode( INARGTYPE element, CNode* pPrev,
CNode* pNext )
{
GetFreeNode();
CNode* pNewNode = m_pFree;
CNode* pNextFree = m_pFree->m_pNext;
::new( pNewNode ) CNode( element );
m_pFree = pNextFree;
pNewNode->m_pPrev = pPrev;
pNewNode->m_pNext = pNext;
m_nElements++;
ATLASSERT( m_nElements > 0 );
return( pNewNode );
}
#pragma pop_macro("new")
template< typename E, class ETraits >
void CAtlList< E, ETraits >::FreeNode( CNode* pNode )
{
pNode->~CNode();
pNode->m_pNext = m_pFree;
m_pFree = pNode;
ATLASSERT( m_nElements > 0 );
m_nElements--;
if( m_nElements == 0 )
{
RemoveAll();
}
}
template< typename E, class ETraits >
POSITION CAtlList< E, ETraits >::AddHead()
{
CNode* pNode = NewNode( NULL, m_pHead );
if( m_pHead != NULL )
{
m_pHead->m_pPrev = pNode;
}
else
{
m_pTail = pNode;
}
m_pHead = pNode;
return( POSITION( pNode ) );
}
template< typename E, class ETraits >
POSITION CAtlList< E, ETraits >::AddHead( INARGTYPE element )
{
CNode* pNode;
pNode = NewNode( element, NULL, m_pHead );
if( m_pHead != NULL )
{
m_pHead->m_pPrev = pNode;
}
else
{
m_pTail = pNode;
}
m_pHead = pNode;
return( POSITION( pNode ) );
}
template< typename E, class ETraits >
POSITION CAtlList< E, ETraits >::AddTail()
{
CNode* pNode = NewNode( m_pTail, NULL );
if( m_pTail != NULL )
{
m_pTail->m_pNext = pNode;
}
else
{
m_pHead = pNode;
}
m_pTail = pNode;
return( POSITION( pNode ) );
}
template< typename E, class ETraits >
POSITION CAtlList< E, ETraits >::AddTail( INARGTYPE element )
{
CNode* pNode;
pNode = NewNode( element, m_pTail, NULL );
if( m_pTail != NULL )
{
m_pTail->m_pNext = pNode;
}
else
{
m_pHead = pNode;
}
m_pTail = pNode;
return( POSITION( pNode ) );
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::AddHeadList( const CAtlList< E, ETraits >* plNew )
{
POSITION pos;
ATLASSERT( plNew != NULL );
pos = plNew->GetTailPosition();
while( pos != NULL )
{
INARGTYPE element = plNew->GetPrev( pos );
AddHead( element );
}
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::AddTailList( const CAtlList< E, ETraits >* plNew )
{
POSITION pos;
ATLASSERT( plNew != NULL );
pos = plNew->GetHeadPosition();
while( pos != NULL )
{
INARGTYPE element = plNew->GetNext( pos );
AddTail( element );
}
}
template< typename E, class ETraits >
E CAtlList< E, ETraits >::RemoveHead()
{
CNode* pNode;
ATLASSERT( m_pHead != NULL );
pNode = m_pHead;
E element( pNode->m_element );
m_pHead = pNode->m_pNext;
if( m_pHead != NULL )
{
m_pHead->m_pPrev = NULL;
}
else
{
m_pTail = NULL;
}
FreeNode( pNode );
return( element );
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::RemoveHeadNoReturn() throw()
{
ATLASSERT( m_pHead != NULL );
CNode* pNode = m_pHead;
m_pHead = pNode->m_pNext;
if( m_pHead != NULL )
{
m_pHead->m_pPrev = NULL;
}
else
{
m_pTail = NULL;
}
FreeNode( pNode );
}
template< typename E, class ETraits >
E CAtlList< E, ETraits >::RemoveTail()
{
CNode* pNode;
ATLASSERT( m_pTail != NULL );
pNode = m_pTail;
E element( pNode->m_element );
m_pTail = pNode->m_pPrev;
if( m_pTail != NULL )
{
m_pTail->m_pNext = NULL;
}
else
{
m_pHead = NULL;
}
FreeNode( pNode );
return( element );
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::RemoveTailNoReturn() throw()
{
ATLASSERT( m_pTail != NULL );
CNode* pNode = m_pTail;
m_pTail = pNode->m_pPrev;
if( m_pTail != NULL )
{
m_pTail->m_pNext = NULL;
}
else
{
m_pHead = NULL;
}
FreeNode( pNode );
}
template< typename E, class ETraits >
POSITION CAtlList< E, ETraits >::InsertBefore( POSITION pos, INARGTYPE element )
{
ATLASSERT_VALID(this);
if( pos == NULL )
return AddHead( element ); // insert before nothing -> head of the list
// Insert it before position
CNode* pOldNode = (CNode*)pos;
CNode* pNewNode = NewNode( element, pOldNode->m_pPrev, pOldNode );
if( pOldNode->m_pPrev != NULL )
{
ATLASSERT(AtlIsValidAddress(pOldNode->m_pPrev, sizeof(CNode)));
pOldNode->m_pPrev->m_pNext = pNewNode;
}
else
{
ATLASSERT( pOldNode == m_pHead );
m_pHead = pNewNode;
}
pOldNode->m_pPrev = pNewNode;
return( POSITION( pNewNode ) );
}
template< typename E, class ETraits >
POSITION CAtlList< E, ETraits >::InsertAfter( POSITION pos, INARGTYPE element )
{
ATLASSERT_VALID(this);
if( pos == NULL )
return AddTail( element ); // insert after nothing -> tail of the list
// Insert it after position
CNode* pOldNode = (CNode*)pos;
CNode* pNewNode = NewNode( element, pOldNode, pOldNode->m_pNext );
if( pOldNode->m_pNext != NULL )
{
ATLASSERT(AtlIsValidAddress(pOldNode->m_pNext, sizeof(CNode)));
pOldNode->m_pNext->m_pPrev = pNewNode;
}
else
{
ATLASSERT( pOldNode == m_pTail );
m_pTail = pNewNode;
}
pOldNode->m_pNext = pNewNode;
return( POSITION( pNewNode ) );
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::RemoveAt( POSITION pos )
{
ATLASSERT_VALID(this);
CNode* pOldNode = (CNode*)pos;
ATLASSERT(AtlIsValidAddress(pOldNode, sizeof(CNode)));
// remove pOldNode from list
if( pOldNode == m_pHead )
{
m_pHead = pOldNode->m_pNext;
}
else
{
ATLASSERT(AtlIsValidAddress(pOldNode->m_pPrev, sizeof(CNode)));
pOldNode->m_pPrev->m_pNext = pOldNode->m_pNext;
}
if( pOldNode == m_pTail )
{
m_pTail = pOldNode->m_pPrev;
}
else
{
ATLASSERT(AtlIsValidAddress(pOldNode->m_pNext, sizeof(CNode)));
pOldNode->m_pNext->m_pPrev = pOldNode->m_pPrev;
}
FreeNode( pOldNode );
}
template< typename E, class ETraits >
POSITION CAtlList< E, ETraits >::FindIndex( size_t iElement ) const
{
ATLASSERT_VALID(this);
if( iElement >= m_nElements )
return NULL; // went too far
CNode* pNode = m_pHead;
for( size_t iSearch = 0; iSearch < iElement; iSearch++ )
{
pNode = pNode->m_pNext;
}
return( POSITION( pNode ) );
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::MoveToHead( POSITION pos ) throw()
{
ATLASSERT( pos != NULL );
CNode* pNode = static_cast< CNode* >( pos );
if( pNode == m_pHead )
{
// Already at the head
return;
}
if( pNode->m_pNext == NULL )
{
ATLASSERT( pNode == m_pTail );
m_pTail = pNode->m_pPrev;
}
else
{
pNode->m_pNext->m_pPrev = pNode->m_pPrev;
}
ATLASSERT( pNode->m_pPrev != NULL ); // This node can't be the head, since we already checked that case
pNode->m_pPrev->m_pNext = pNode->m_pNext;
m_pHead->m_pPrev = pNode;
pNode->m_pNext = m_pHead;
pNode->m_pPrev = NULL;
m_pHead = pNode;
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::MoveToTail( POSITION pos ) throw()
{
ATLASSERT( pos != NULL );
CNode* pNode = static_cast< CNode* >( pos );
if( pNode == m_pTail )
{
// Already at the tail
return;
}
if( pNode->m_pPrev == NULL )
{
ATLASSERT( pNode == m_pHead );
m_pHead = pNode->m_pNext;
}
else
{
pNode->m_pPrev->m_pNext = pNode->m_pNext;
}
ATLASSERT( pNode->m_pNext != NULL ); // This node can't be the tail, since we already checked that case
pNode->m_pNext->m_pPrev = pNode->m_pPrev;
m_pTail->m_pNext = pNode;
pNode->m_pPrev = m_pTail;
pNode->m_pNext = NULL;
m_pTail = pNode;
}
template< typename E, class ETraits >
void CAtlList< E, ETraits >::SwapElements( POSITION pos1, POSITION pos2 ) throw()
{
ATLASSERT( pos1 != NULL );
ATLASSERT( pos2 != NULL );
if( pos1 == pos2 )
{
// Nothing to do
return;
}
CNode* pNode1 = static_cast< CNode* >( pos1 );
CNode* pNode2 = static_cast< CNode* >( pos2 );
if( pNode2->m_pNext == pNode1 )
{
// Swap pNode2 and pNode1 so that the next case works
CNode* pNodeTemp = pNode1;
pNode1 = pNode2;
pNode2 = pNodeTemp;
}
if( pNode1->m_pNext == pNode2 )
{
// Node1 and Node2 are adjacent
pNode2->m_pPrev = pNode1->m_pPrev;
if( pNode1->m_pPrev != NULL )
{
pNode1->m_pPrev->m_pNext = pNode2;
}
else
{
ATLASSERT( m_pHead == pNode1 );
m_pHead = pNode2;
}
pNode1->m_pNext = pNode2->m_pNext;
if( pNode2->m_pNext != NULL )
{
pNode2->m_pNext->m_pPrev = pNode1;
}
else
{
ATLASSERT( m_pTail == pNode2 );
m_pTail = pNode1;
}
pNode2->m_pNext = pNode1;
pNode1->m_pPrev = pNode2;
}
else
{
// The two nodes are not adjacent
CNode* pNodeTemp;
pNodeTemp = pNode1->m_pPrev;
pNode1->m_pPrev = pNode2->m_pPrev;
pNode2->m_pPrev = pNodeTemp;
pNodeTemp = pNode1->m_pNext;
pNode1->m_pNext = pNode2->m_pNext;
pNode2->m_pNext = pNodeTemp;
if( pNode1->m_pNext != NULL )
{
pNode1->m_pNext->m_pPrev = pNode1;
}
else
{
ATLASSERT( m_pTail == pNode2 );
m_pTail = pNode1;
}
if( pNode1->m_pPrev != NULL )
{
pNode1->m_pPrev->m_pNext = pNode1;
}
else
{
ATLASSERT( m_pHead == pNode2 );
m_pHead = pNode1;
}
if( pNode2->m_pNext != NULL )
{
pNode2->m_pNext->m_pPrev = pNode2;
}
else
{
ATLASSERT( m_pTail == pNode1 );
m_pTail = pNode2;
}
if( pNode2->m_pPrev != NULL )
{
pNode2->m_pPrev->m_pNext = pNode2;
}
else
{
ATLASSERT( m_pHead == pNode1 );
m_pHead = pNode2;
}
}
}
template< typename E, class ETraits >
POSITION CAtlList< E, ETraits >::Find( INARGTYPE element, POSITION posStartAfter ) const
{
ATLASSERT_VALID(this);
CNode* pNode = (CNode*)posStartAfter;
if( pNode == NULL )
{
pNode = m_pHead; // start at head
}
else
{
ATLASSERT(AtlIsValidAddress(pNode, sizeof(CNode)));
pNode = pNode->m_pNext; // start after the one specified
}
for( ; pNode != NULL; pNode = pNode->m_pNext )
{
if( ETraits::CompareElements( pNode->m_element, element ) )
return( POSITION( pNode ) );
}
return( NULL );
}
#ifdef _DEBUG
template< typename E, class ETraits >
void CAtlList< E, ETraits >::AssertValid() const
{
if( IsEmpty() )
{
// empty list
ATLASSERT(m_pHead == NULL);
ATLASSERT(m_pTail == NULL);
}
else
{
// non-empty list
ATLASSERT(AtlIsValidAddress(m_pHead, sizeof(CNode)));
ATLASSERT(AtlIsValidAddress(m_pTail, sizeof(CNode)));
}
}
#endif
template< typename K, typename V, class KTraits = CElementTraits< K >, class VTraits = CElementTraits< V > >
class CAtlMap
{
public:
typedef KTraits::INARGTYPE KINARGTYPE;
typedef KTraits::OUTARGTYPE KOUTARGTYPE;
typedef VTraits::INARGTYPE VINARGTYPE;
typedef VTraits::OUTARGTYPE VOUTARGTYPE;
class CPair :
public __POSITION
{
protected:
CPair( KINARGTYPE key ) :
m_key( key )
{
}
public:
const K m_key;
V m_value;
};
private:
class CNode :
public CPair
{
public:
CNode( KINARGTYPE key, UINT nHash ) :
CPair( key ),
m_nHash( nHash )
{
}
public:
UINT GetHash() const throw()
{
return( m_nHash );
}
public:
CNode* m_pNext;
UINT m_nHash;
};
public:
CAtlMap( UINT nBins = 17, float fOptimalLoad = 0.75f,
float fLoThreshold = 0.25f, float fHiThreshold = 2.25f, UINT nBlockSize = 10 ) throw();
size_t GetCount() const throw();
bool IsEmpty() const throw();
bool Lookup( KINARGTYPE key, VOUTARGTYPE value ) const;
const CPair* Lookup( KINARGTYPE key ) const throw();
CPair* Lookup( KINARGTYPE key ) throw();
V& operator[]( KINARGTYPE key ) throw();
POSITION SetAt( KINARGTYPE key, VINARGTYPE value );
void SetValueAt( POSITION pos, VINARGTYPE value );
bool RemoveKey( KINARGTYPE key ) throw();
void RemoveAll() throw();
void RemoveAtPos( POSITION pos ) throw();
POSITION GetStartPosition() const throw();
void GetNextAssoc( POSITION& pos, KOUTARGTYPE key, VOUTARGTYPE value ) const;
const CPair* GetNext( POSITION& pos ) const throw();
CPair* GetNext( POSITION& pos ) throw();
const K& GetNextKey( POSITION& pos ) const throw();
const V& GetNextValue( POSITION& pos ) const throw();
V& GetNextValue( POSITION& pos ) throw();
void GetAt( POSITION pos, KOUTARGTYPE key, VOUTARGTYPE value ) const;
CPair* GetAt( POSITION pos ) throw();
const CPair* GetAt( POSITION pos ) const throw();
const K& GetKeyAt( POSITION pos ) const throw();
const V& GetValueAt( POSITION pos ) const throw();
V& GetValueAt( POSITION pos ) throw();
UINT GetHashTableSize() const throw();
bool InitHashTable( UINT nBins, bool bAllocNow = true );
void EnableAutoRehash() throw();
void DisableAutoRehash() throw();
void Rehash( UINT nBins = 0 );
void SetOptimalLoad( float fOptimalLoad, float fLoThreshold, float fHiThreshold,
bool bRehashNow = false );
#ifdef _DEBUG
void AssertValid() const;
#endif // _DEBUG
// Implementation
private:
CNode** m_ppBins;
size_t m_nElements;
UINT m_nBins;
float m_fOptimalLoad;
float m_fLoThreshold;
float m_fHiThreshold;
size_t m_nHiRehashThreshold;
size_t m_nLoRehashThreshold;
ULONG m_nLockCount;
UINT m_nBlockSize;
CAtlPlex* m_pBlocks;
CNode* m_pFree;
private:
bool IsLocked() const throw();
UINT PickSize( size_t nElements ) const throw();
CNode* NewNode( KINARGTYPE key, UINT iBin, UINT nHash );
void FreeNode( CNode* pNode ) throw();
void FreePlexes() throw();
CNode* GetNode( KINARGTYPE key, UINT& iBin, UINT& nHash, CNode*& pPrev ) const throw();
CNode* CreateNode( KINARGTYPE key, UINT iBin, UINT nHash );
void RemoveNode( CNode* pNode, CNode* pPrev ) throw();
CNode* FindNextNode( CNode* pNode ) const throw();
void UpdateRehashThresholds() throw();
public:
~CAtlMap() throw();
private:
// Private to prevent use
CAtlMap( const CAtlMap& ) throw();
CAtlMap& operator=( const CAtlMap& ) throw();
};
template< typename K, typename I, class KTraits = CElementTraits< K > >
class CMapToInterface :
public CAtlMap< K, ATL::CComQIPtr< I >, KTraits, CComQIPtrElementTraits< I > >
{
public:
CMapToInterface( UINT nBins = 17 ) throw();
private:
// Private to prevent use
CMapToInterface( const CMapToInterface& ) throw();
CMapToInterface& operator=( const CMapToInterface& ) throw();
};
template< typename K, typename I, class KTraits >
inline CMapToInterface< K, I, KTraits >::CMapToInterface( UINT nBins ) :
CAtlMap< K, ATL::CComQIPtr< I >, KTraits, CComQIPtrElementTraits< I > >( nBins )
{
}
template< typename K, typename V, class KTraits = CElementTraits< K > >
class CMapToAutoPtr :
public CAtlMap< K, ATL::CAutoPtr< V >, KTraits, CAutoPtrElementTraits< V > >
{
public:
CMapToAutoPtr( UINT nBins = 17 ) throw();
private:
// Private to prevent use
CMapToAutoPtr( const CMapToAutoPtr& ) throw();
CMapToAutoPtr& operator=( const CMapToAutoPtr& ) throw();
};
template< typename K, typename V, class KTraits >
inline CMapToAutoPtr< K, V, KTraits >::CMapToAutoPtr( UINT nBins ) :
CAtlMap< K, ATL::CAutoPtr< V >, KTraits, CAutoPtrElementTraits< V > >( nBins )
{
}
template< typename K, typename V, class KTraits, class VTraits >
inline size_t CAtlMap< K, V, KTraits, VTraits >::GetCount() const
{
return( m_nElements );
}
template< typename K, typename V, class KTraits, class VTraits >
inline bool CAtlMap< K, V, KTraits, VTraits >::IsEmpty() const
{
return( m_nElements == 0 );
}
template< typename K, typename V, class KTraits, class VTraits >
inline V& CAtlMap< K, V, KTraits, VTraits >::operator[]( KINARGTYPE key )
{
CNode* pNode;
UINT iBin;
UINT nHash;
CNode* pPrev;
pNode = GetNode( key, iBin, nHash, pPrev );
if( pNode == NULL )
{
pNode = CreateNode( key, iBin, nHash );
}
return( pNode->m_value );
}
template< typename K, typename V, class KTraits, class VTraits >
inline UINT CAtlMap< K, V, KTraits, VTraits >::GetHashTableSize() const
{
return( m_nBins );
}
template< typename K, typename V, class KTraits, class VTraits >
inline void CAtlMap< K, V, KTraits, VTraits >::GetAt( POSITION pos, KOUTARGTYPE key, VOUTARGTYPE value ) const
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = static_cast< CNode* >( pos );
key = pNode->m_key;
value = pNode->m_value;
}
template< typename K, typename V, class KTraits, class VTraits >
inline CAtlMap< K, V, KTraits, VTraits >::CPair* CAtlMap< K, V, KTraits, VTraits >::GetAt( POSITION pos ) throw()
{
ATLASSERT( pos != NULL );
return( static_cast< CPair* >( pos ) );
}
template< typename K, typename V, class KTraits, class VTraits >
inline const CAtlMap< K, V, KTraits, VTraits >::CPair* CAtlMap< K, V, KTraits, VTraits >::GetAt( POSITION pos ) const throw()
{
ATLASSERT( pos != NULL );
return( static_cast< const CPair* >( pos ) );
}
template< typename K, typename V, class KTraits, class VTraits >
inline const K& CAtlMap< K, V, KTraits, VTraits >::GetKeyAt( POSITION pos ) const
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
return( pNode->m_key );
}
template< typename K, typename V, class KTraits, class VTraits >
inline const V& CAtlMap< K, V, KTraits, VTraits >::GetValueAt( POSITION pos ) const
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
return( pNode->m_value );
}
template< typename K, typename V, class KTraits, class VTraits >
inline V& CAtlMap< K, V, KTraits, VTraits >::GetValueAt( POSITION pos )
{
CNode* pNode;
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
return( pNode->m_value );
}
template< typename K, typename V, class KTraits, class VTraits >
inline void CAtlMap< K, V, KTraits, VTraits >::DisableAutoRehash() throw()
{
m_nLockCount++;
}
template< typename K, typename V, class KTraits, class VTraits >
inline void CAtlMap< K, V, KTraits, VTraits >::EnableAutoRehash() throw()
{
ATLASSERT( m_nLockCount > 0 );
m_nLockCount--;
}
template< typename K, typename V, class KTraits, class VTraits >
inline bool CAtlMap< K, V, KTraits, VTraits >::IsLocked() const
{
return( m_nLockCount != 0 );
}
template< typename K, typename V, class KTraits, class VTraits >
UINT CAtlMap< K, V, KTraits, VTraits >::PickSize( size_t nElements ) const
{
// List of primes such that s_anPrimes[i] is the smallest prime greater than 2^(5+i/3)
static const UINT s_anPrimes[] =
{
17, 23, 29, 37, 41, 53, 67, 83, 103, 131, 163, 211, 257, 331, 409, 521, 647, 821,
1031, 1291, 1627, 2053, 2591, 3251, 4099, 5167, 6521, 8209, 10331,
13007, 16411, 20663, 26017, 32771, 41299, 52021, 65537, 82571, 104033,
131101, 165161, 208067, 262147, 330287, 416147, 524309, 660563,
832291, 1048583, 1321139, 1664543, 2097169, 2642257, 3329023, 4194319,
5284493, 6658049, 8388617, 10568993, 13316089, UINT_MAX
};
UINT nBinsEstimate = UINT( min( UINT_MAX, (size_t)(nElements/m_fOptimalLoad) ) );
// Find the smallest prime greater than our estimate
int iPrime = 0;
while( nBinsEstimate > s_anPrimes[iPrime] )
{
iPrime++;
}
if( s_anPrimes[iPrime] == UINT_MAX )
{
return( nBinsEstimate );
}
else
{
return( s_anPrimes[iPrime] );
}
}
template< typename K, typename V, class KTraits, class VTraits >
CAtlMap< K, V, KTraits, VTraits >::CNode* CAtlMap< K, V, KTraits, VTraits >::CreateNode(
KINARGTYPE key, UINT iBin, UINT nHash )
{
CNode* pNode;
if( m_ppBins == NULL )
{
bool bSuccess;
bSuccess = InitHashTable( m_nBins );
if( !bSuccess )
{
ATL::AtlThrow( E_OUTOFMEMORY );
}
}
pNode = NewNode( key, iBin, nHash );
return( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
POSITION CAtlMap< K, V, KTraits, VTraits >::GetStartPosition() const
{
if( IsEmpty() )
{
return( NULL );
}
for( UINT iBin = 0; iBin < m_nBins; iBin++ )
{
if( m_ppBins[iBin] != NULL )
{
return( POSITION( m_ppBins[iBin] ) );
}
}
ATLASSERT( false );
return( NULL );
}
template< typename K, typename V, class KTraits, class VTraits >
POSITION CAtlMap< K, V, KTraits, VTraits >::SetAt( KINARGTYPE key, VINARGTYPE value )
{
CNode* pNode;
UINT iBin;
UINT nHash;
CNode* pPrev;
pNode = GetNode( key, iBin, nHash, pPrev );
if( pNode == NULL )
{
pNode = CreateNode( key, iBin, nHash );
_ATLTRY
{
pNode->m_value = value;
}
_ATLCATCHALL()
{
RemoveAtPos( POSITION( pNode ) );
_ATLRETHROW;
}
}
else
{
pNode->m_value = value;
}
return( POSITION( pNode ) );
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::SetValueAt( POSITION pos, VINARGTYPE value )
{
ATLASSERT( pos != NULL );
CNode* pNode = static_cast< CNode* >( pos );
pNode->m_value = value;
}
template< typename K, typename V, class KTraits, class VTraits >
CAtlMap< K, V, KTraits, VTraits >::CAtlMap( UINT nBins, float fOptimalLoad,
float fLoThreshold, float fHiThreshold, UINT nBlockSize ) :
m_ppBins( NULL ),
m_nBins( nBins ),
m_nElements( 0 ),
m_nLockCount( 0 ), // Start unlocked
m_fOptimalLoad( fOptimalLoad ),
m_fLoThreshold( fLoThreshold ),
m_fHiThreshold( fHiThreshold ),
m_nHiRehashThreshold( UINT_MAX ),
m_nLoRehashThreshold( 0 ),
m_pBlocks( NULL ),
m_pFree( NULL ),
m_nBlockSize( nBlockSize )
{
ATLASSERT( nBins > 0 );
ATLASSERT( nBlockSize > 0 );
SetOptimalLoad( fOptimalLoad, fLoThreshold, fHiThreshold, false );
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::SetOptimalLoad( float fOptimalLoad, float fLoThreshold,
float fHiThreshold, bool bRehashNow )
{
ATLASSERT( fOptimalLoad > 0 );
ATLASSERT( (fLoThreshold >= 0) && (fLoThreshold < fOptimalLoad) );
ATLASSERT( fHiThreshold > fOptimalLoad );
m_fOptimalLoad = fOptimalLoad;
m_fLoThreshold = fLoThreshold;
m_fHiThreshold = fHiThreshold;
UpdateRehashThresholds();
if( bRehashNow && ((m_nElements > m_nHiRehashThreshold) ||
(m_nElements < m_nLoRehashThreshold)) )
{
Rehash( PickSize( m_nElements ) );
}
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::UpdateRehashThresholds() throw()
{
m_nHiRehashThreshold = size_t( m_fHiThreshold*m_nBins );
m_nLoRehashThreshold = size_t( m_fLoThreshold*m_nBins );
if( m_nLoRehashThreshold < 17 )
{
m_nLoRehashThreshold = 0;
}
}
template< typename K, typename V, class KTraits, class VTraits >
bool CAtlMap< K, V, KTraits, VTraits >::InitHashTable( UINT nBins, bool bAllocNow )
{
ATLASSERT( m_nElements == 0 );
ATLASSERT( nBins > 0 );
if( m_ppBins != NULL )
{
delete[] m_ppBins;
m_ppBins = NULL;
}
if( bAllocNow )
{
ATLTRY( m_ppBins = new CNode*[nBins] );
if( m_ppBins == NULL )
{
return false;
}
memset( m_ppBins, 0, sizeof( CNode* )*nBins );
}
m_nBins = nBins;
UpdateRehashThresholds();
return true;
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::RemoveAll()
{
DisableAutoRehash();
if( m_ppBins != NULL )
{
for( UINT iBin = 0; iBin < m_nBins; iBin++ )
{
CNode* pNext;
pNext = m_ppBins[iBin];
while( pNext != NULL )
{
CNode* pKill;
pKill = pNext;
pNext = pNext->m_pNext;
FreeNode( pKill );
}
}
}
delete[] m_ppBins;
m_ppBins = NULL;
m_nElements = 0;
if( !IsLocked() )
{
InitHashTable( PickSize( m_nElements ), false );
}
FreePlexes();
EnableAutoRehash();
}
template< typename K, typename V, class KTraits, class VTraits >
CAtlMap< K, V, KTraits, VTraits >::~CAtlMap()
{
RemoveAll();
}
#pragma push_macro("new")
#undef new
template< typename K, typename V, class KTraits, class VTraits >
CAtlMap< K, V, KTraits, VTraits >::CNode* CAtlMap< K, V, KTraits, VTraits >::NewNode(
KINARGTYPE key, UINT iBin, UINT nHash )
{
CNode* pNewNode;
if( m_pFree == NULL )
{
CAtlPlex* pPlex;
CNode* pNode;
pPlex = CAtlPlex::Create( m_pBlocks, m_nBlockSize, sizeof( CNode ) );
if( pPlex == NULL )
{
ATL::AtlThrow( E_OUTOFMEMORY );
}
pNode = (CNode*)pPlex->data();
pNode += m_nBlockSize-1;
for( int iBlock = m_nBlockSize-1; iBlock >= 0; iBlock-- )
{
pNode->m_pNext = m_pFree;
m_pFree = pNode;
pNode--;
}
}
ATLASSERT( m_pFree != NULL );
pNewNode = m_pFree;
m_pFree = pNewNode->m_pNext;
_ATLTRY
{
::new( pNewNode ) CNode( key, nHash );
}
_ATLCATCHALL()
{
pNewNode->m_pNext = m_pFree;
m_pFree = pNewNode;
_ATLRETHROW;
}
m_nElements++;
pNewNode->m_pNext = m_ppBins[iBin];
m_ppBins[iBin] = pNewNode;
if( (m_nElements > m_nHiRehashThreshold) && !IsLocked() )
{
Rehash( PickSize( m_nElements ) );
}
return( pNewNode );
}
#pragma pop_macro("new")
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::FreeNode( CNode* pNode )
{
ATLASSERT( pNode != NULL );
pNode->~CNode();
pNode->m_pNext = m_pFree;
m_pFree = pNode;
ATLASSERT( m_nElements > 0 );
m_nElements--;
if( (m_nElements < m_nLoRehashThreshold) && !IsLocked() )
{
Rehash( PickSize( m_nElements ) );
}
if( m_nElements == 0 )
{
FreePlexes();
}
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::FreePlexes() throw()
{
m_pFree = NULL;
if( m_pBlocks != NULL )
{
m_pBlocks->FreeDataChain();
m_pBlocks = NULL;
}
}
template< typename K, typename V, class KTraits, class VTraits >
CAtlMap< K, V, KTraits, VTraits >::CNode* CAtlMap< K, V, KTraits, VTraits >::GetNode(
KINARGTYPE key, UINT& iBin, UINT& nHash, CNode*& pPrev ) const
{
CNode* pFollow;
nHash = KTraits::Hash( key );
iBin = nHash%m_nBins;
if( m_ppBins == NULL )
{
return( NULL );
}
pFollow = NULL;
pPrev = NULL;
for( CNode* pNode = m_ppBins[iBin]; pNode != NULL; pNode = pNode->m_pNext )
{
if( (pNode->GetHash() == nHash) && KTraits::CompareElements( pNode->m_key, key ) )
{
pPrev = pFollow;
return( pNode );
}
pFollow = pNode;
}
return( NULL );
}
template< typename K, typename V, class KTraits, class VTraits >
bool CAtlMap< K, V, KTraits, VTraits >::Lookup( KINARGTYPE key, VOUTARGTYPE value ) const
{
UINT iBin;
UINT nHash;
CNode* pNode;
CNode* pPrev;
pNode = GetNode( key, iBin, nHash, pPrev );
if( pNode == NULL )
{
return( false );
}
value = pNode->m_value;
return( true );
}
template< typename K, typename V, class KTraits, class VTraits >
const CAtlMap< K, V, KTraits, VTraits >::CPair* CAtlMap< K, V, KTraits, VTraits >::Lookup( KINARGTYPE key ) const
{
UINT iBin;
UINT nHash;
CNode* pNode;
CNode* pPrev;
pNode = GetNode( key, iBin, nHash, pPrev );
return( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
CAtlMap< K, V, KTraits, VTraits >::CPair* CAtlMap< K, V, KTraits, VTraits >::Lookup( KINARGTYPE key )
{
UINT iBin;
UINT nHash;
CNode* pNode;
CNode* pPrev;
pNode = GetNode( key, iBin, nHash, pPrev );
return( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
bool CAtlMap< K, V, KTraits, VTraits >::RemoveKey( KINARGTYPE key )
{
CNode* pNode;
UINT iBin;
UINT nHash;
CNode* pPrev;
pPrev = NULL;
pNode = GetNode( key, iBin, nHash, pPrev );
if( pNode == NULL )
{
return( false );
}
RemoveNode( pNode, pPrev );
return( true );
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::RemoveNode( CNode* pNode, CNode* pPrev )
{
UINT iBin;
ATLASSERT( pNode != NULL );
iBin = pNode->GetHash()%m_nBins;
if( pPrev == NULL )
{
ATLASSERT( m_ppBins[iBin] == pNode );
m_ppBins[iBin] = pNode->m_pNext;
}
else
{
ATLASSERT( pPrev->m_pNext == pNode );
pPrev->m_pNext = pNode->m_pNext;
}
FreeNode( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::RemoveAtPos( POSITION pos )
{
CNode* pNode;
CNode* pPrev;
UINT iBin;
ATLASSERT( pos != NULL );
pNode = static_cast< CNode* >( pos );
iBin = pNode->GetHash()%m_nBins;
ATLASSERT( m_ppBins[iBin] != NULL );
if( pNode == m_ppBins[iBin] )
{
pPrev = NULL;
}
else
{
pPrev = m_ppBins[iBin];
while( pPrev->m_pNext != pNode )
{
pPrev = pPrev->m_pNext;
ATLASSERT( pPrev != NULL );
}
}
RemoveNode( pNode, pPrev );
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::Rehash( UINT nBins )
{
CNode** ppBins = NULL;
if( nBins == 0 )
{
nBins = PickSize( m_nElements );
}
if( nBins == m_nBins )
{
return;
}
ATLTRACE(atlTraceMap, 2, _T("Rehash: %u bins\n"), nBins );
if( m_ppBins == NULL )
{
// Just set the new number of bins
InitHashTable( nBins, false );
return;
}
ATLTRY(ppBins = new CNode*[nBins]);
if (ppBins == NULL)
{
ATL::AtlThrow( E_OUTOFMEMORY );
}
memset( ppBins, 0, nBins*sizeof( CNode* ) );
// Nothing gets copied. We just rewire the old nodes
// into the new bins.
for( UINT iSrcBin = 0; iSrcBin < m_nBins; iSrcBin++ )
{
CNode* pNode;
pNode = m_ppBins[iSrcBin];
while( pNode != NULL )
{
CNode* pNext;
UINT iDestBin;
pNext = pNode->m_pNext; // Save so we don't trash it
iDestBin = pNode->GetHash()%nBins;
pNode->m_pNext = ppBins[iDestBin];
ppBins[iDestBin] = pNode;
pNode = pNext;
}
}
delete[] m_ppBins;
m_ppBins = ppBins;
m_nBins = nBins;
UpdateRehashThresholds();
}
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::GetNextAssoc( POSITION& pos, KOUTARGTYPE key,
VOUTARGTYPE value ) const
{
CNode* pNode;
CNode* pNext;
ATLASSERT( m_ppBins != NULL );
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pNext = FindNextNode( pNode );
pos = POSITION( pNext );
key = pNode->m_key;
value = pNode->m_value;
}
template< typename K, typename V, class KTraits, class VTraits >
const CAtlMap< K, V, KTraits, VTraits >::CPair* CAtlMap< K, V, KTraits, VTraits >::GetNext( POSITION& pos ) const
{
CNode* pNode;
CNode* pNext;
ATLASSERT( m_ppBins != NULL );
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pNext = FindNextNode( pNode );
pos = POSITION( pNext );
return( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
CAtlMap< K, V, KTraits, VTraits >::CPair* CAtlMap< K, V, KTraits, VTraits >::GetNext(
POSITION& pos ) throw()
{
ATLASSERT( m_ppBins != NULL );
ATLASSERT( pos != NULL );
CNode* pNode = static_cast< CNode* >( pos );
CNode* pNext = FindNextNode( pNode );
pos = POSITION( pNext );
return( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
const K& CAtlMap< K, V, KTraits, VTraits >::GetNextKey( POSITION& pos ) const
{
CNode* pNode;
CNode* pNext;
ATLASSERT( m_ppBins != NULL );
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pNext = FindNextNode( pNode );
pos = POSITION( pNext );
return( pNode->m_key );
}
template< typename K, typename V, class KTraits, class VTraits >
const V& CAtlMap< K, V, KTraits, VTraits >::GetNextValue( POSITION& pos ) const
{
CNode* pNode;
CNode* pNext;
ATLASSERT( m_ppBins != NULL );
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pNext = FindNextNode( pNode );
pos = POSITION( pNext );
return( pNode->m_value );
}
template< typename K, typename V, class KTraits, class VTraits >
V& CAtlMap< K, V, KTraits, VTraits >::GetNextValue( POSITION& pos )
{
CNode* pNode;
CNode* pNext;
ATLASSERT( m_ppBins != NULL );
ATLASSERT( pos != NULL );
pNode = (CNode*)pos;
pNext = FindNextNode( pNode );
pos = POSITION( pNext );
return( pNode->m_value );
}
template< typename K, typename V, class KTraits, class VTraits >
CAtlMap< K, V, KTraits, VTraits >::CNode* CAtlMap< K, V, KTraits, VTraits >::FindNextNode( CNode* pNode ) const
{
CNode* pNext;
if( pNode->m_pNext != NULL )
{
pNext = pNode->m_pNext;
}
else
{
UINT iBin;
pNext = NULL;
iBin = (pNode->GetHash()%m_nBins)+1;
while( (pNext == NULL) && (iBin < m_nBins) )
{
if( m_ppBins[iBin] != NULL )
{
pNext = m_ppBins[iBin];
}
iBin++;
}
}
return( pNext );
}
#ifdef _DEBUG
template< typename K, typename V, class KTraits, class VTraits >
void CAtlMap< K, V, KTraits, VTraits >::AssertValid() const
{
ATLASSERT( m_nBins > 0 );
// non-empty map should have hash table
ATLASSERT( IsEmpty() || (m_ppBins != NULL) );
}
#endif
#pragma push_macro("new")
#undef new
//
// The red-black tree code is based on the the descriptions in
// "Introduction to Algorithms", by Cormen, Leiserson, and Rivest
//
template< typename K, typename V, class KTraits = CElementTraits< K >, class VTraits = CElementTraits< V > >
class CRBTree
{
public:
typedef KTraits::INARGTYPE KINARGTYPE;
typedef KTraits::OUTARGTYPE KOUTARGTYPE;
typedef VTraits::INARGTYPE VINARGTYPE;
typedef VTraits::OUTARGTYPE VOUTARGTYPE;
public:
class CPair :
public __POSITION
{
protected:
CPair( KINARGTYPE key, VINARGTYPE value ) :
m_key( key ),
m_value( value )
{
}
~CPair() throw()
{
}
public:
const K m_key;
V m_value;
};
private:
class CNode :
public CPair
{
public:
enum RB_COLOR
{
RB_RED,
RB_BLACK
};
public:
RB_COLOR m_eColor;
CNode* m_pLeft;
CNode* m_pRight;
CNode* m_pParent;
CNode( KINARGTYPE key, VINARGTYPE value ) :
CPair( key, value ),
m_pParent( NULL ),
m_eColor( RB_BLACK )
{
}
~CNode() throw()
{
}
};
private:
CNode* m_pRoot;
size_t m_nCount;
CNode* m_pFree;
CAtlPlex* m_pBlocks;
size_t m_nBlockSize;
// sentinel node
CNode *m_pNil;
// methods
bool IsNil(CNode *p) const throw();
void SetNil(CNode **p) throw();
CNode* NewNode( KINARGTYPE key, VINARGTYPE value ) throw( ... );
void FreeNode(CNode* pNode) throw();
void RemovePostOrder(CNode* pNode) throw();
CNode* LeftRotate(CNode* pNode) throw();
CNode* RightRotate(CNode* pNode) throw();
void SwapNode(CNode* pDest, CNode* pSrc) throw();
CNode* InsertImpl( KINARGTYPE key, VINARGTYPE value ) throw( ... );
void RBDeleteFixup(CNode* pNode) throw();
bool RBDelete(CNode* pZ) throw();
#ifdef _DEBUG
// internal debugging code to verify red-black properties of tree:
// 1) Every node is either red or black
// 2) Every leaf (NIL) is black
// 3) If a node is red, both its children are black
// 4) Every simple path from a node to a descendant leaf node contains
// the same number of black nodes
private:
void VerifyIntegrity(const CNode *pNode, int nCurrBlackDepth, int &nBlackDepth) const throw();
public:
void VerifyIntegrity() const throw();
#endif // _DEBUG
protected:
CNode* Minimum(CNode* pNode) const throw();
CNode* Maximum(CNode* pNode) const throw();
CNode* Predecessor( CNode* pNode ) const throw();
CNode* Successor(CNode* pNode) const throw();
CNode* RBInsert( KINARGTYPE key, VINARGTYPE value ) throw( ... );
CNode* Find(KINARGTYPE key) const throw();
CNode* FindPrefix( KINARGTYPE key ) const throw();
protected:
explicit CRBTree( size_t nBlockSize = 10 ) throw(); // protected to prevent instantiation
public:
~CRBTree() throw();
void RemoveAll() throw();
void RemoveAt(POSITION pos) throw();
size_t GetCount() const throw();
bool IsEmpty() const throw();
POSITION FindFirstKeyAfter( KINARGTYPE key ) const throw();
POSITION GetHeadPosition() const throw();
POSITION GetTailPosition() const throw();
void GetNextAssoc( POSITION& pos, KOUTARGTYPE key, VOUTARGTYPE value ) const;
const CPair* GetNext(POSITION& pos) const throw();
CPair* GetNext(POSITION& pos) throw();
const CPair* GetPrev(POSITION& pos) const throw();
CPair* GetPrev(POSITION& pos) throw();
const K& GetNextKey(POSITION& pos) const throw();
const V& GetNextValue(POSITION& pos) const throw();
V& GetNextValue(POSITION& pos) throw();
CPair* GetAt( POSITION pos ) throw();
const CPair* GetAt( POSITION pos ) const throw();
void GetAt(POSITION pos, KOUTARGTYPE key, VOUTARGTYPE value) const;
const K& GetKeyAt(POSITION pos) const throw();
const V& GetValueAt(POSITION pos) const throw();
V& GetValueAt(POSITION pos) throw();
void SetValueAt(POSITION pos, VINARGTYPE value);
private:
// Private to prevent use
CRBTree( const CRBTree& ) throw();
CRBTree& operator=( const CRBTree& ) throw();
};
template< typename K, typename V, class KTraits, class VTraits >
inline bool CRBTree< K, V, KTraits, VTraits >::IsNil(CNode *p) const
{
return ( p == m_pNil );
}
template< typename K, typename V, class KTraits, class VTraits >
inline void CRBTree< K, V, KTraits, VTraits >::SetNil(CNode **p)
{
ATLASSERT( p != NULL );
*p = m_pNil;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CRBTree( size_t nBlockSize ) throw() :
m_pRoot( NULL ),
m_nCount( 0 ),
m_nBlockSize( nBlockSize ),
m_pFree( NULL ),
m_pBlocks( NULL ),
m_pNil( NULL )
{
ATLASSERT( nBlockSize > 0 );
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::~CRBTree() throw()
{
RemoveAll();
if (m_pNil != NULL)
{
free(m_pNil);
}
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::RemoveAll() throw()
{
if (!IsNil(m_pRoot))
RemovePostOrder(m_pRoot);
m_nCount = 0;
m_pBlocks->FreeDataChain();
m_pBlocks = NULL;
m_pFree = NULL;
m_pRoot = m_pNil;
}
template< typename K, typename V, class KTraits, class VTraits >
size_t CRBTree< K, V, KTraits, VTraits >::GetCount() const throw()
{
return m_nCount;
}
template< typename K, typename V, class KTraits, class VTraits >
bool CRBTree< K, V, KTraits, VTraits >::IsEmpty() const throw()
{
return( m_nCount == 0 );
}
template< typename K, typename V, class KTraits, class VTraits >
POSITION CRBTree< K, V, KTraits, VTraits >::FindFirstKeyAfter( KINARGTYPE key ) const throw()
{
return( FindPrefix( key ) );
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::RemoveAt(POSITION pos) throw()
{
ATLASSERT(pos != NULL);
RBDelete(static_cast<CNode*>(pos));
}
template< typename K, typename V, class KTraits, class VTraits >
POSITION CRBTree< K, V, KTraits, VTraits >::GetHeadPosition() const throw()
{
return( Minimum( m_pRoot ) );
}
template< typename K, typename V, class KTraits, class VTraits >
POSITION CRBTree< K, V, KTraits, VTraits >::GetTailPosition() const throw()
{
return( Maximum( m_pRoot ) );
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::GetNextAssoc( POSITION& pos, KOUTARGTYPE key, VOUTARGTYPE value ) const
{
ATLASSERT(pos != NULL);
CNode* pNode = static_cast< CNode* >(pos);
key = pNode->m_key;
value = pNode->m_value;
pos = Successor(pNode);
}
template< typename K, typename V, class KTraits, class VTraits >
const CRBTree< K, V, KTraits, VTraits >::CPair* CRBTree< K, V, KTraits, VTraits >::GetNext(POSITION& pos) const throw()
{
ATLASSERT(pos != NULL);
CNode* pNode = static_cast< CNode* >(pos);
pos = Successor(pNode);
return pNode;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CPair* CRBTree< K, V, KTraits, VTraits >::GetNext(POSITION& pos) throw()
{
ATLASSERT(pos != NULL);
CNode* pNode = static_cast< CNode* >(pos);
pos = Successor(pNode);
return pNode;
}
template< typename K, typename V, class KTraits, class VTraits >
const CRBTree< K, V, KTraits, VTraits >::CPair* CRBTree< K, V, KTraits, VTraits >::GetPrev(POSITION& pos) const throw()
{
ATLASSERT(pos != NULL);
CNode* pNode = static_cast< CNode* >(pos);
pos = Predecessor(pNode);
return pNode;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CPair* CRBTree< K, V, KTraits, VTraits >::GetPrev(POSITION& pos) throw()
{
ATLASSERT(pos != NULL);
CNode* pNode = static_cast< CNode* >(pos);
pos = Predecessor(pNode);
return pNode;
}
template< typename K, typename V, class KTraits, class VTraits >
const K& CRBTree< K, V, KTraits, VTraits >::GetNextKey(POSITION& pos) const throw()
{
ATLASSERT(pos != NULL);
CNode* pNode = static_cast<CNode*>(pos);
pos = Successor(pNode);
return pNode->m_key;
}
template< typename K, typename V, class KTraits, class VTraits >
const V& CRBTree< K, V, KTraits, VTraits >::GetNextValue(POSITION& pos) const throw()
{
ATLASSERT(pos != NULL);
CNode* pNode = static_cast<CNode*>(pos);
pos = Successor(pNode);
return pNode->m_value;
}
template< typename K, typename V, class KTraits, class VTraits >
V& CRBTree< K, V, KTraits, VTraits >::GetNextValue(POSITION& pos) throw()
{
ATLASSERT(pos != NULL);
CNode* pNode = static_cast<CNode*>(pos);
pos = Successor(pNode);
return pNode->m_value;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CPair* CRBTree< K, V, KTraits, VTraits >::GetAt( POSITION pos ) throw()
{
ATLASSERT( pos != NULL );
return( static_cast< CPair* >( pos ) );
}
template< typename K, typename V, class KTraits, class VTraits >
const CRBTree< K, V, KTraits, VTraits >::CPair* CRBTree< K, V, KTraits, VTraits >::GetAt( POSITION pos ) const throw()
{
ATLASSERT( pos != NULL );
return( static_cast< const CPair* >( pos ) );
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::GetAt(POSITION pos, KOUTARGTYPE key, VOUTARGTYPE value) const
{
ATLASSERT(pos != NULL);
key = static_cast<CNode*>(pos)->m_key;
value = static_cast<CNode*>(pos)->m_value;
}
template< typename K, typename V, class KTraits, class VTraits >
const K& CRBTree< K, V, KTraits, VTraits >::GetKeyAt(POSITION pos) const throw()
{
ATLASSERT(pos != NULL);
return static_cast<CNode*>(pos)->m_key;
}
template< typename K, typename V, class KTraits, class VTraits >
const V& CRBTree< K, V, KTraits, VTraits >::GetValueAt(POSITION pos) const throw()
{
ATLASSERT(pos != NULL);
return static_cast<CNode*>(pos)->m_value;
}
template< typename K, typename V, class KTraits, class VTraits >
V& CRBTree< K, V, KTraits, VTraits >::GetValueAt(POSITION pos) throw()
{
ATLASSERT(pos != NULL);
return static_cast<CNode*>(pos)->m_value;
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::SetValueAt(POSITION pos, VINARGTYPE value)
{
ATLASSERT(pos != NULL);
static_cast<CNode*>(pos)->m_value = value;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::NewNode( KINARGTYPE key, VINARGTYPE value ) throw( ... )
{
if( m_pFree == NULL )
{
if (m_pNil == NULL)
{
m_pNil = reinterpret_cast<CNode *>(malloc(sizeof( CNode )));
if (m_pNil == NULL)
{
AtlThrow( E_OUTOFMEMORY );
}
memset(m_pNil, 0x00, sizeof(CNode));
m_pNil->m_eColor = CNode::RB_BLACK;
m_pNil->m_pParent = m_pNil->m_pLeft = m_pNil->m_pRight = m_pNil;
m_pRoot = m_pNil;
}
CAtlPlex* pPlex = CAtlPlex::Create( m_pBlocks, m_nBlockSize, sizeof( CNode ) );
if( pPlex == NULL )
{
AtlThrow( E_OUTOFMEMORY );
}
CNode* pNode = static_cast< CNode* >( pPlex->data() );
pNode += m_nBlockSize-1;
for( INT_PTR iBlock = m_nBlockSize-1; iBlock >= 0; iBlock-- )
{
pNode->m_pLeft = m_pFree;
m_pFree = pNode;
pNode--;
}
}
ATLASSERT( m_pFree != NULL );
CNode* pNewNode = m_pFree;
::new( pNewNode ) CNode( key, value );
m_pFree = m_pFree->m_pLeft;
pNewNode->m_eColor = CNode::RB_RED;
SetNil(&pNewNode->m_pLeft);
SetNil(&pNewNode->m_pRight);
SetNil(&pNewNode->m_pParent);
m_nCount++;
ATLASSERT( m_nCount > 0 );
return( pNewNode );
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::FreeNode(CNode* pNode) throw()
{
ATLASSERT(pNode != NULL);
pNode->~CNode();
pNode->m_pLeft = m_pFree;
m_pFree = pNode;
ATLASSERT( m_nCount > 0 );
m_nCount--;
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::RemovePostOrder(CNode* pNode) throw()
{
if (IsNil(pNode))
return;
RemovePostOrder(pNode->m_pLeft);
RemovePostOrder(pNode->m_pRight);
FreeNode( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::LeftRotate(CNode* pNode) throw()
{
ATLASSERT(pNode != NULL);
CNode* pRight = pNode->m_pRight;
pNode->m_pRight = pRight->m_pLeft;
if (!IsNil(pRight->m_pLeft))
pRight->m_pLeft->m_pParent = pNode;
pRight->m_pParent = pNode->m_pParent;
if (IsNil(pNode->m_pParent))
m_pRoot = pRight;
else if (pNode == pNode->m_pParent->m_pLeft)
pNode->m_pParent->m_pLeft = pRight;
else
pNode->m_pParent->m_pRight = pRight;
pRight->m_pLeft = pNode;
pNode->m_pParent = pRight;
return pNode;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::RightRotate(CNode* pNode) throw()
{
ATLASSERT(pNode != NULL);
CNode* pLeft = pNode->m_pLeft;
pNode->m_pLeft = pLeft->m_pRight;
if (!IsNil(pLeft->m_pRight))
pLeft->m_pRight->m_pParent = pNode;
pLeft->m_pParent = pNode->m_pParent;
if (IsNil(pNode->m_pParent))
m_pRoot = pLeft;
else if (pNode == pNode->m_pParent->m_pRight)
pNode->m_pParent->m_pRight = pLeft;
else
pNode->m_pParent->m_pLeft = pLeft;
pLeft->m_pRight = pNode;
pNode->m_pParent = pLeft;
return pNode;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::Find(KINARGTYPE key) const throw()
{
CNode* pKey = NULL;
CNode* pNode = m_pRoot;
while( !IsNil(pNode) && (pKey == NULL) )
{
int nCompare = KTraits::CompareElementsOrdered( key, pNode->m_key );
if( nCompare == 0 )
{
pKey = pNode;
}
else
{
if( nCompare < 0 )
{
pNode = pNode->m_pLeft;
}
else
{
pNode = pNode->m_pRight;
}
}
}
if( pKey == NULL )
{
return( NULL );
}
#pragma warning(push)
#pragma warning(disable:4127)
while( true )
{
CNode* pPrev = Predecessor( pKey );
if( (pPrev != NULL) && KTraits::CompareElements( key, pPrev->m_key ) )
{
pKey = pPrev;
}
else
{
return( pKey );
}
}
#pragma warning(pop)
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::FindPrefix( KINARGTYPE key ) const throw()
{
// First, attempt to find a node that matches the key exactly
CNode* pParent = NULL;
CNode* pKey = NULL;
CNode* pNode = m_pRoot;
while( !IsNil(pNode) && (pKey == NULL) )
{
pParent = pNode;
int nCompare = KTraits::CompareElementsOrdered( key, pNode->m_key );
if( nCompare == 0 )
{
pKey = pNode;
}
else if( nCompare < 0 )
{
pNode = pNode->m_pLeft;
}
else
{
pNode = pNode->m_pRight;
}
}
if( pKey != NULL )
{
// We found a node with the exact key, so find the first node in
// the tree with that key by walking backwards until we find a node
// that doesn't match the key
while( true )
{
CNode* pPrev = Predecessor( pKey );
if( (pPrev != NULL) && KTraits::CompareElements( key, pPrev->m_key ) )
{
pKey = pPrev;
}
else
{
return( pKey );
}
}
}
else if (pParent != NULL)
{
// No node matched the key exactly, so pick the first node with
// a key greater than the given key
int nCompare = KTraits::CompareElementsOrdered( key, pParent->m_key );
if( nCompare < 0 )
{
pKey = pParent;
}
else
{
ATLASSERT( nCompare > 0 );
pKey = Successor( pParent );
}
}
return( pKey );
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::SwapNode(CNode* pDest, CNode* pSrc) throw()
{
ATLASSERT(pDest != NULL);
ATLASSERT(pSrc != NULL);
pDest->m_pParent = pSrc->m_pParent;
if (pSrc->m_pParent->m_pLeft == pSrc)
pSrc->m_pParent->m_pLeft = pDest;
else
pSrc->m_pParent->m_pRight = pDest;
pDest->m_pRight = pSrc->m_pRight;
pDest->m_pLeft = pSrc->m_pLeft;
pDest->m_eColor = pSrc->m_eColor;
pDest->m_pRight->m_pParent = pDest;
pDest->m_pLeft->m_pParent = pDest;
if (m_pRoot == pSrc)
{
m_pRoot = pDest;
}
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::InsertImpl( KINARGTYPE key, VINARGTYPE value ) throw( ... )
{
CNode* pNew = NewNode( key, value );
CNode* pY = NULL;
CNode* pX = m_pRoot;
while (!IsNil(pX))
{
pY = pX;
if( KTraits::CompareElementsOrdered( key, pX->m_key ) <= 0 )
pX = pX->m_pLeft;
else
pX = pX->m_pRight;
}
pNew->m_pParent = pY;
if (pY == NULL)
{
m_pRoot = pNew;
}
else if( KTraits::CompareElementsOrdered( key, pY->m_key ) <= 0 )
pY->m_pLeft = pNew;
else
pY->m_pRight = pNew;
return pNew;
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::RBDeleteFixup(CNode* pNode) throw()
{
CNode* pX = pNode;
CNode* pW = NULL;
while (pX != m_pRoot && pX->m_eColor == CNode::RB_BLACK)
{
if (pX == pX->m_pParent->m_pLeft)
{
pW = pX->m_pParent->m_pRight;
if (pW->m_eColor == CNode::RB_RED)
{
pW->m_eColor = CNode::RB_BLACK;
pW->m_pParent->m_eColor = CNode::RB_RED;
LeftRotate(pX->m_pParent);
pW = pX->m_pParent->m_pRight;
}
if (pW->m_pLeft->m_eColor == CNode::RB_BLACK && pW->m_pRight->m_eColor == CNode::RB_BLACK)
{
pW->m_eColor = CNode::RB_RED;
pX = pX->m_pParent;
}
else
{
if (pW->m_pRight->m_eColor == CNode::RB_BLACK)
{
pW->m_pLeft->m_eColor = CNode::RB_BLACK;
pW->m_eColor = CNode::RB_RED;
RightRotate(pW);
pW = pX->m_pParent->m_pRight;
}
pW->m_eColor = pX->m_pParent->m_eColor;
pX->m_pParent->m_eColor = CNode::RB_BLACK;
pW->m_pRight->m_eColor = CNode::RB_BLACK;
LeftRotate(pX->m_pParent);
pX = m_pRoot;
}
}
else
{
pW = pX->m_pParent->m_pLeft;
if (pW->m_eColor == CNode::RB_RED)
{
pW->m_eColor = CNode::RB_BLACK;
pW->m_pParent->m_eColor = CNode::RB_RED;
RightRotate(pX->m_pParent);
pW = pX->m_pParent->m_pLeft;
}
if (pW->m_pRight->m_eColor == CNode::RB_BLACK && pW->m_pLeft->m_eColor == CNode::RB_BLACK)
{
pW->m_eColor = CNode::RB_RED;
pX = pX->m_pParent;
}
else
{
if (pW->m_pLeft->m_eColor == CNode::RB_BLACK)
{
pW->m_pRight->m_eColor = CNode::RB_BLACK;
pW->m_eColor = CNode::RB_RED;
LeftRotate(pW);
pW = pX->m_pParent->m_pLeft;
}
pW->m_eColor = pX->m_pParent->m_eColor;
pX->m_pParent->m_eColor = CNode::RB_BLACK;
pW->m_pLeft->m_eColor = CNode::RB_BLACK;
RightRotate(pX->m_pParent);
pX = m_pRoot;
}
}
}
pX->m_eColor = CNode::RB_BLACK;
}
template< typename K, typename V, class KTraits, class VTraits >
bool CRBTree< K, V, KTraits, VTraits >::RBDelete(CNode* pZ) throw()
{
if (pZ == NULL)
return false;
CNode* pY = NULL;
CNode* pX = NULL;
if (IsNil(pZ->m_pLeft) || IsNil(pZ->m_pRight))
pY = pZ;
else
pY = Successor(pZ);
if (!IsNil(pY->m_pLeft))
pX = pY->m_pLeft;
else
pX = pY->m_pRight;
pX->m_pParent = pY->m_pParent;
if (IsNil(pY->m_pParent))
m_pRoot = pX;
else if (pY == pY->m_pParent->m_pLeft)
pY->m_pParent->m_pLeft = pX;
else
pY->m_pParent->m_pRight = pX;
if (pY->m_eColor == CNode::RB_BLACK)
RBDeleteFixup(pX);
if (pY != pZ)
SwapNode(pY, pZ);
if (m_pRoot != NULL)
SetNil(&m_pRoot->m_pParent);
FreeNode( pZ );
return true;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::Minimum(CNode* pNode) const throw()
{
if (pNode == NULL || IsNil(pNode))
{
return NULL;
}
CNode* pMin = pNode;
while (!IsNil(pMin->m_pLeft))
{
pMin = pMin->m_pLeft;
}
return pMin;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::Maximum(CNode* pNode) const throw()
{
if (pNode == NULL || IsNil(pNode))
{
return NULL;
}
CNode* pMax = pNode;
while (!IsNil(pMax->m_pRight))
{
pMax = pMax->m_pRight;
}
return pMax;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::Predecessor( CNode* pNode ) const throw()
{
if( pNode == NULL )
{
return( NULL );
}
if( !IsNil(pNode->m_pLeft) )
{
return( Maximum( pNode->m_pLeft ) );
}
CNode* pParent = pNode->m_pParent;
CNode* pLeft = pNode;
while( !IsNil(pParent) && (pLeft == pParent->m_pLeft) )
{
pLeft = pParent;
pParent = pParent->m_pParent;
}
if (IsNil(pParent))
{
pParent = NULL;
}
return( pParent );
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::Successor(CNode* pNode) const throw()
{
if ( pNode == NULL )
{
return NULL;
}
if ( !IsNil(pNode->m_pRight) )
{
return Minimum(pNode->m_pRight);
}
CNode* pParent = pNode->m_pParent;
CNode* pRight = pNode;
while ( !IsNil(pParent) && (pRight == pParent->m_pRight) )
{
pRight = pParent;
pParent = pParent->m_pParent;
}
if (IsNil(pParent))
{
pParent = NULL;
}
return pParent;
}
template< typename K, typename V, class KTraits, class VTraits >
CRBTree< K, V, KTraits, VTraits >::CNode* CRBTree< K, V, KTraits, VTraits >::RBInsert( KINARGTYPE key, VINARGTYPE value ) throw( ... )
{
CNode* pNewNode = InsertImpl( key, value );
CNode* pX = pNewNode;
pX->m_eColor = CNode::RB_RED;
CNode* pY = NULL;
while (pX != m_pRoot && pX->m_pParent->m_eColor == CNode::RB_RED)
{
if (pX->m_pParent == pX->m_pParent->m_pParent->m_pLeft)
{
pY = pX->m_pParent->m_pParent->m_pRight;
if (pY != NULL && pY->m_eColor == CNode::RB_RED)
{
pX->m_pParent->m_eColor = CNode::RB_BLACK;
pY->m_eColor = CNode::RB_BLACK;
pX->m_pParent->m_pParent->m_eColor = CNode::RB_RED;
pX = pX->m_pParent->m_pParent;
}
else
{
if (pX == pX->m_pParent->m_pRight)
{
pX = pX->m_pParent;
LeftRotate(pX);
}
pX->m_pParent->m_eColor = CNode::RB_BLACK;
pX->m_pParent->m_pParent->m_eColor = CNode::RB_RED;
RightRotate(pX->m_pParent->m_pParent);
}
}
else
{
pY = pX->m_pParent->m_pParent->m_pLeft;
if (pY != NULL && pY->m_eColor == CNode::RB_RED)
{
pX->m_pParent->m_eColor = CNode::RB_BLACK;
pY->m_eColor = CNode::RB_BLACK;
pX->m_pParent->m_pParent->m_eColor = CNode::RB_RED;
pX = pX->m_pParent->m_pParent;
}
else
{
if (pX == pX->m_pParent->m_pLeft)
{
pX = pX->m_pParent;
RightRotate(pX);
}
pX->m_pParent->m_eColor = CNode::RB_BLACK;
pX->m_pParent->m_pParent->m_eColor = CNode::RB_RED;
LeftRotate(pX->m_pParent->m_pParent);
}
}
}
m_pRoot->m_eColor = CNode::RB_BLACK;
SetNil(&m_pRoot->m_pParent);
return( pNewNode );
}
#ifdef _DEBUG
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::VerifyIntegrity(const CNode *pNode, int nCurrBlackDepth, int &nBlackDepth) const
{
bool bCheckForBlack = false;
bool bLeaf = true;
if (pNode->m_eColor == CNode::RB_RED)
bCheckForBlack = true;
else
nCurrBlackDepth++;
ATLASSERT(pNode->m_pLeft != NULL);
if (!IsNil(pNode->m_pLeft))
{
bLeaf = false;
if (bCheckForBlack)
{
ATLASSERT(pNode->m_pLeft->m_eColor == CNode::RB_BLACK);
}
VerifyIntegrity(pNode->m_pLeft, nCurrBlackDepth, nBlackDepth);
}
ATLASSERT(pNode->m_pRight != NULL);
if (!IsNil(pNode->m_pRight))
{
bLeaf = false;
if (bCheckForBlack)
{
ATLASSERT(pNode->m_pRight->m_eColor == CNode::RB_BLACK);
}
VerifyIntegrity(pNode->m_pRight, nCurrBlackDepth, nBlackDepth);
}
ATLASSERT( pNode->m_pParent != NULL );
ATLASSERT( ( IsNil(pNode->m_pParent) ) ||
( pNode->m_pParent->m_pLeft == pNode ) ||
( pNode->m_pParent->m_pRight == pNode ) );
if (bLeaf)
{
if (nBlackDepth == 0)
{
nBlackDepth = nCurrBlackDepth;
}
else
{
ATLASSERT(nBlackDepth == nCurrBlackDepth);
}
}
}
template< typename K, typename V, class KTraits, class VTraits >
void CRBTree< K, V, KTraits, VTraits >::VerifyIntegrity() const
{
if ((m_pRoot == NULL) || (IsNil(m_pRoot)))
return;
ATLASSERT(m_pRoot->m_eColor == CNode::RB_BLACK);
int nBlackDepth = 0;
VerifyIntegrity(m_pRoot, 0, nBlackDepth);
}
#endif // _DEBUG
template< typename K, typename V, class KTraits = CElementTraits< K >, class VTraits = CElementTraits< V > >
class CRBMap :
public CRBTree< K, V, KTraits, VTraits >
{
public:
explicit CRBMap( size_t nBlockSize = 10 ) throw();
~CRBMap() throw();
bool Lookup( KINARGTYPE key, VOUTARGTYPE value ) const throw( ... );
const CPair* Lookup( KINARGTYPE key ) const throw();
CPair* Lookup( KINARGTYPE key ) throw();
POSITION SetAt( KINARGTYPE key, VINARGTYPE value ) throw( ... );
bool RemoveKey( KINARGTYPE key ) throw();
};
template< typename K, typename V, class KTraits, class VTraits >
CRBMap< K, V, KTraits, VTraits >::CRBMap( size_t nBlockSize ) throw() :
CRBTree< K, V, KTraits, VTraits >( nBlockSize )
{
}
template< typename K, typename V, class KTraits, class VTraits >
CRBMap< K, V, KTraits, VTraits >::~CRBMap() throw()
{
}
template< typename K, typename V, class KTraits, class VTraits >
const CRBMap< K, V, KTraits, VTraits >::CPair* CRBMap< K, V, KTraits, VTraits >::Lookup( KINARGTYPE key ) const throw()
{
return Find(key);
}
template< typename K, typename V, class KTraits, class VTraits >
CRBMap< K, V, KTraits, VTraits >::CPair* CRBMap< K, V, KTraits, VTraits >::Lookup( KINARGTYPE key ) throw()
{
return Find(key);
}
template< typename K, typename V, class KTraits, class VTraits >
bool CRBMap< K, V, KTraits, VTraits >::Lookup( KINARGTYPE key, VOUTARGTYPE value ) const throw( ... )
{
const CPair* pLookup = Find( key );
if( pLookup == NULL )
return false;
value = pLookup->m_value;
return true;
}
template< typename K, typename V, class KTraits, class VTraits >
POSITION CRBMap< K, V, KTraits, VTraits >::SetAt( KINARGTYPE key, VINARGTYPE value ) throw( ... )
{
CPair* pNode = Find( key );
if( pNode == NULL )
{
return( RBInsert( key, value ) );
}
else
{
pNode->m_value = value;
return( pNode );
}
}
template< typename K, typename V, class KTraits, class VTraits >
bool CRBMap< K, V, KTraits, VTraits >::RemoveKey( KINARGTYPE key ) throw()
{
POSITION pos = Lookup( key );
if( pos != NULL )
{
RemoveAt( pos );
return( true );
}
else
{
return( false );
}
}
template< typename K, typename V, class KTraits = CElementTraits< K >, class VTraits = CElementTraits< V > >
class CRBMultiMap :
public CRBTree< K, V, KTraits, VTraits >
{
public:
explicit CRBMultiMap( size_t nBlockSize = 10 ) throw();
~CRBMultiMap() throw();
POSITION Insert( KINARGTYPE key, VINARGTYPE value ) throw( ... );
size_t RemoveKey( KINARGTYPE key ) throw();
POSITION FindFirstWithKey( KINARGTYPE key ) const throw();
const CPair* GetNextWithKey( POSITION& pos, KINARGTYPE key ) const throw();
CPair* GetNextWithKey( POSITION& pos, KINARGTYPE key ) throw();
const V& GetNextValueWithKey( POSITION& pos, KINARGTYPE key ) const throw();
V& GetNextValueWithKey( POSITION& pos, KINARGTYPE key ) throw();
};
template< typename K, typename V, class KTraits, class VTraits >
CRBMultiMap< K, V, KTraits, VTraits >::CRBMultiMap( size_t nBlockSize ) throw() :
CRBTree< K, V, KTraits, VTraits >( nBlockSize )
{
}
template< typename K, typename V, class KTraits, class VTraits >
CRBMultiMap< K, V, KTraits, VTraits >::~CRBMultiMap() throw()
{
}
template< typename K, typename V, class KTraits, class VTraits >
POSITION CRBMultiMap< K, V, KTraits, VTraits >::Insert( KINARGTYPE key, VINARGTYPE value ) throw( ... )
{
return( RBInsert( key, value ) );
}
template< typename K, typename V, class KTraits, class VTraits >
size_t CRBMultiMap< K, V, KTraits, VTraits >::RemoveKey( KINARGTYPE key ) throw()
{
size_t nElementsDeleted = 0;
POSITION pos = FindFirstWithKey( key );
while( pos != NULL )
{
POSITION posDelete = pos;
GetNextWithKey( pos, key );
RemoveAt( posDelete );
nElementsDeleted++;
}
return( nElementsDeleted );
}
template< typename K, typename V, class KTraits, class VTraits >
POSITION CRBMultiMap< K, V, KTraits, VTraits >::FindFirstWithKey( KINARGTYPE key ) const throw()
{
return( Find( key ) );
}
template< typename K, typename V, class KTraits, class VTraits >
const CRBMultiMap< K, V, KTraits, VTraits >::CPair* CRBMultiMap< K, V, KTraits, VTraits >::GetNextWithKey( POSITION& pos, KINARGTYPE key ) const throw()
{
ATLASSERT( pos != NULL );
const CPair* pNode = GetNext( pos );
if( (pos == NULL) || !KTraits::CompareElements( static_cast< CPair* >( pos )->m_key, key ) )
{
pos = NULL;
}
return( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
CRBMultiMap< K, V, KTraits, VTraits >::CPair* CRBMultiMap< K, V, KTraits, VTraits >::GetNextWithKey( POSITION& pos, KINARGTYPE key ) throw()
{
ATLASSERT( pos != NULL );
CPair* pNode = GetNext( pos );
if( (pos == NULL) || !KTraits::CompareElements( static_cast< CPair* >( pos )->m_key, key ) )
{
pos = NULL;
}
return( pNode );
}
template< typename K, typename V, class KTraits, class VTraits >
const V& CRBMultiMap< K, V, KTraits, VTraits >::GetNextValueWithKey( POSITION& pos, KINARGTYPE key ) const throw()
{
const CPair* pPair = GetNextWithKey( pos, key );
return( pPair->m_value );
}
template< typename K, typename V, class KTraits, class VTraits >
V& CRBMultiMap< K, V, KTraits, VTraits >::GetNextValueWithKey( POSITION& pos, KINARGTYPE key ) throw()
{
CPair* pPair = GetNextWithKey( pos, key );
return( pPair->m_value );
}
#pragma pop_macro("new")
}; // namespace ATL
//REVIEW: Just to fix VSEE
#pragma pop_macro("min")
#pragma pop_macro("max")
#pragma warning(pop)
#endif // __ATLCOLL_H__